Download The Role Of Spinal Serotonergic Receptors 5-Ht1a And 5

THE ROLE OF SPINAL SEROTONERGIC RECEPTORS 5-HT1A AND 5-HT3 IN
STRESS-INDUCED URINARY BLADDER HYPERSENSITIVITY
by
CHELSEA L. CRAWFORD
MEREDITH T. ROBBINS, COMMITTEE CHAIR
FRANKLIN R. AMTHOR
EDWIN C. COOK
TIMOTHY J. NESS
ROBERT E. SORGE
A DISSERTATION
Submitted to the graduate faculty of The University of Alabama at Birmingham,
in partial fulfillment of the requirements for the degree of
Doctor of Philosophy
BIRMINGHAM, ALABAMA
2014
Copyright by
Chelsea L. Crawford
2014
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THE ROLE OF SPINAL SEROTONERGIC RECEPTORS 5-HT1A AND 5-HT3 IN
STRESS-INDUCED URINARY BLADDER HYPERSENSITIVITY
CHELSEA L. CRAWFORD
BEHAVIORAL NEUROSCIENCE
ABSTRACT
Disorders in which pain originates from the urinary bladder such as interstitial cystitis
(IC) are steadily increasing in prevalence. A common finding among patients with IC is
the comorbidity with stress or anxiety disorders. In rats, footshock stress alone is
sufficient to elicit bladder hypersensitivity. Serotonin (5-hydroxytryptamine; 5-HT) has
been established as a mediator in anxiety and pain separately, but little is known about
the role of 5-HT in stress-induced visceral hypersensitivity. The current set of studies
addresses three main concerns: (1) the impact of spinal 5-HT1A and 5-HT3 receptor
blockade with WAY-100635 (10 µg) and ondansetron (10 µg), respectively, on
visceromotor reflex (VMR) responses to urinary bladder distension (UBD) of rats
exposed to chronic footshock stress, (2) the impact of chronic footshock stress on spinal
and cerebrospinal fluid 5-HT, 5-HIAA, and 5-HIAA/5-HT concentrations, and (3) the
impact of spinal 5-HT3 receptor blockade with ondansetron (100 µg ) on dorsal horn
neuronal responses to UBD. Experiments used to test these concerns utilized Lewis rats,
a strain which has not been used in studies of stress-induced bladder hypersensitivity. A
significant increase in abdominal EMG responses to UBD was observed in rats exposed
to chronic footshock stress compared to sham stress. Intrathecal WAY-100635 or
ondansetron had no significant effect on abdominal EMG responses to UBD in stressed
or non-stressed rats. Chronic footshock stress did not significantly alter spinal or CSF
concentrations of 5-HT, 5-HIAA, or 5-HIAA/5-HT. Spinal application of ondansetron
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did not significantly alter neuronal responses to UBD in stressed or non-stressed rats. In
light of these findings, preliminary results demonstrate that spinal non-specific 5-HT
receptor blockade with methysergide (30 µg) significantly augmented the VMR response
to UBD. Therefore, these results indicate that 5-HT is involved in the facilitation of
stress-induced bladder hypersensitivity, but this facilitation does not rely exclusively on
activation of either spinal 5-HT1A or 5-HT3 receptors.
Keywords: bladder, visceral pain, stress, serotonin, interstitial cystitis
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DEDICATION
To my husband, Scott, who has always shown me unwavering
love and support throughout this occasionally “stressful” life. And to our two
beautiful children, Elliotte and Dylan, to whom I looked to for the inspiration and
determination to accomplish this goal.
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ACKNOWLEDGEMENTS
I would like to thank God for providing such a mysterious and wonderful world
that I have the great pleasure of trying to figure out.
I want to thank my family, both born of and married into, for always supporting
and encouraging my educational endeavors. They helped me set forth my goals and
made me confident that I could achieve them.
I would especially like to thank Dr. Meredith Robbins for mentoring me both
professionally and personally while working on this dissertation and throughout my
graduate training. I would also like to thank the other members of my dissertation
committee, Dr. Franklin Amthor, Dr. Edwin Cook, Dr. Timothy Ness, and Dr. Robert
Sorge, for their contribution of suggestions and critiques throughout this process.
Few people have made such a lasting impression on my career and life as the
three men of science I am about to mention. Nettles Moore ignited my passion for
questioning everything in our physical world. Dr. Jim Daniels helped to cultivate this
passion by constantly encouraging and checking in on me to be sure that I was using my
skills to contribute to the scientific body of knowledge. Dr. Alan Randich challenged and
cheered me on from my lofty dream of entering graduate school through the completion
of my dissertation. Each of these men took the time to personally acknowledge my
strengths and abilities and to provide the positive reinforcement needed to succeed in
academia.
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I finally want to thank all of my friends, past and present, who have shown
support and stood by me through the highs and lows and all of the life changes that have
occurred during this time in graduate school.
I am eternally grateful.
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TABLE OF CONTENTS
Page
ABSTRACT .............................................................................................................. iii
DEDICATION .......................................................................................................... v
ACKNOWLEDGEMENTS ...................................................................................... vi
LIST OF TABLES .................................................................................................... xi
LIST OF FIGURES ................................................................................................... xii
LIST OF ABBREVIATIONS ................................................................................... xiii
CHAPTER
1
INTRODUCTION ......................................................................................... 1
1.1 The Clinical Problem ............................................................................. 1
1.2 Purpose .................................................................................................. 3
1.3 Hypotheses and Specific Aims .............................................................. 3
2
BACKGROUND ........................................................................................... 6
2.1 Pain: Physiology and Modulation .......................................................... 6
2.1.1 Transmission of Pain ................................................................... 6
2.1.2 Descending Modulation of Pain .................................................. 8
2.1.3 Diffuse Noxious Inhibitory Control ............................................ 11
2.2 Stress: Physiology and Role in Pain Perception ..................................... 13
2.2.1 Physiology of Stress Response .................................................... 15
2.2.2 Models of Laboratory Stress ....................................................... 16
2.2.3 Stress as an Analgesic ................................................................. 18
2.2.4 Stress as an Exacerbator or Pain .................................................. 18
2.3 Serotonin: Physiological Function and Role in
Stress and Pain Systems ......................................................................... 19
2.3.1 Serotonergic Receptors/Function ................................................ 19
2.3.2 Relationship of Serotonin and Stress ........................................... 25
2.3.3 Serotonergic Pain Modulation ..................................................... 26
2.4 Urinary Bladder: Physiology and Interaction
with Stress and Serotonin ....................................................................... 29
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2.4.1 Bladder Innervation ..................................................................... 29
2.4.2 Models of Bladder Nociception................................................... 30
2.4.3 Role of Serotonin in Bladder Function ........................................ 32
2.5 Spinal Neuronal Characterization........................................................... 33
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METHODS .................................................................................................... 36
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
Selection of Species ................................................................................ 36
Anesthesia............................................................................................... 37
Footshock Protocol ................................................................................. 37
Urinary Bladder Distension .................................................................... 38
Receptor Antagonists.............................................................................. 38
Implantation of Intrathecal Catheters ..................................................... 39
Assessment of VMR Response .............................................................. 39
Enzyme-Linked Immunosorbent Assay ................................................. 41
3.8.1 Tissue Collection ......................................................................... 41
3.8.2 Serotonin...................................................................................... 41
3.8.3 5-HIAA ........................................................................................ 42
3.8.4 Corticosterone.............................................................................. 43
3.9 Spinal Electrophysiology........................................................................ 43
3.9.1 Surgical Preparation .................................................................... 43
3.9.2 Quantification of Neuronal Responses ........................................ 44
3.9.3 Neuronal Characterization ........................................................... 44
3.10 Statistical Analyses ............................................................................... 45
3.10.1 Statistical Significance ................................................................ 45
3.10.2 VMR Response ............................................................................ 45
3.10.3 Enyme-Linked Immunosorbent Assay ........................................ 46
3.10.4 Spinal Electrophysiology............................................................. 46
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METHODOLOGICAL DEVELOPMENT ................................................... 48
4.1 Strain Selection ....................................................................................... 48
4.2 Effect of Intrathecal Catheter ................................................................. 51
4.3 Effect of Serotonin on Chronic Footshock-Induced Bladder Pain ......... 53
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RESULTS ...................................................................................................... 60
5.1 Specific Aim 1 ........................................................................................ 60
5.1.1 Purpose ........................................................................................ 60
5.1.2 Effect of Footshock ..................................................................... 60
5.1.3 Effect of WAY 100635 ............................................................... 61
5.1.4 Effect of Ondansetron.................................................................. 61
5.2 Specific Aim 2 ........................................................................................ 62
5.2.1 Purpose ........................................................................................ 62
5.2.2 Enyme-Linked Immunosorbent Assay ........................................ 62
5.3 Specific Aim 3 ........................................................................................ 63
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5.3.1
5.3.2
5.3.3
5.3.4
5.3.5
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Purpose ........................................................................................ 63
Effect of Footshock ..................................................................... 64
Effect of Ondansetron.................................................................. 64
Percent of Baseline Comparisons ................................................ 64
Neuronal Characterization ........................................................... 66
DISCUSSION................................................................................................ 77
6.1 Summary of Results ............................................................................... 77
6.2 Integration of Findings with Current Literature ..................................... 78
6.2.1 The Comorbidity of Chronic Stress and Pain .............................. 78
6.2.2 Serotonin in Stress-Induced Hyperalgesia................................... 80
6.2.3 Dorsal Horn Neuronal Activity in Bladder Pain Models ............ 82
6.3 Discussion of Results ............................................................................. 84
6.3.1 Specific Aim 1 ............................................................................. 84
6.3.2 Specific Aim 2 ............................................................................. 87
6.3.3 Specific Aim 3 ............................................................................. 89
6.4 Strengths ................................................................................................. 91
6.5 Limitations .............................................................................................. 91
6.6 Future Directions .................................................................................... 92
6.7 Conclusions ............................................................................................ 94
LIST OF REFERENCES .......................................................................................... 96
APPENDIX
A IACUC NOTICE OF APPROVAL ................................................................ 121
B IACUC NOTICE OF APPROVAL FOR
PROTOCOL MODIFICATION ..................................................................... 123
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LIST OF TABLES
Table
Page
4.1 Effect of intrathecal catheter on visceromotor reflex responses......................... 59
5.1 Effect of footshock on spinal and CSF 5-HT, 5-HIAA,
and 5-HIAA/5-HT concentrations ...................................................................... 76
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LIST OF FIGURES
Figure
Page
4.1 Effect of rat strain on visceromotor reflex responses ......................................... 55
4.2 Effect of rat strain on serum corticosterone levels ............................................. 56
4.3 Effect of intrathecal catheter on visceromotor reflex responses......................... 57
4.4 Effect of non-specific serontonergic receptor blockade
on visceromotor reflex responses ....................................................................... 58
5.1 Effect of footshock on visceromotor reflex responses ....................................... 67
5.2 Effect of WAY-100635 on visceromotor reflex responses ................................ 68
5.3 Effect of ondansetron on visceromotor reflex responses ................................... 69
5.4 Effect of footshock on spinal and CSF serotonin concentrations....................... 70
5.5 Effect of footshock on spinal and CSF 5-HIAA concentrations ........................ 71
5.6 Effect of footshock on spinal and CSF 5-HIAA/5-HT concentrations .............. 72
5.7 Effect of footshock on dorsal horn neuronal activity ......................................... 73
5.8 Effect of ondansetron on dorsal horn neuronal activity ..................................... 74
5.9 Electrode depth from spinal cord dorsum .......................................................... 75
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LIST OF ABBREVIATIONS
5-HIAA
5-indoleacetic acid
5-HT
5-hydroxytryptamine
5-HTP
5-hydroxytryptaphan
8-OH-DPAT
8-Hydroxy-N,N-dipropyl-2-aminotetralin
ACC
anterior cingulate cortex
ACTH
adrenocorticotropic hormone
ANOVA
analysis of variance
BPS
bladder pain syndrome
cAMP
cyclic adenosine monophosphate
CFS
chronic footshock
CNS
central nervous system
CRF
corticotropin releasing factor
CRD
colorectal distension
CSF
cerebrospinal fluid
DNIC
diffuse noxious inhibitory control
DOI
2,5-dimethoxy-4-iodoamphetamine
E
epinephrine
ELISA
Enzyme-Linked Immunosorbant Assay
EMG
electromyograph
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GABA
γ-aminobutyric acid
GI
gastrointestinal
HNCS
heterotopic noxious conditioning stimuli
HPA
hypothalamic-pituitary-adrenal
IC
interstitial cystitis
LC
locus coeruleus
LS
lumbosacral
LSD
lysergic acid diethylamide
l-STT
lateral spinothalamic tract
MDMA
3,4-methylenedioxy-N-methylamphetamine
NE
norepinephrine
NFS
no footshock
NGC
nucleus reticularis gigantocellularis
NMDA
N-methyl-D-aspartate
NS
nociceptive specific
ODS
ondansetron
PAG
periaqueductal gray
PBS
painful bladder syndrome
PKA
protein kinase A
POMC
pro-opiomelanocortin
PVN
paraventricular nucleus
RNA-i
ribonucleic acid interference
RVM
rostroventral medulla
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SAL
saline
SD
Sprague Dawley
sh-RNA
short hairpin ribonucleic acid
SIA
stress-induced analgesia
SIH
stress-induced hyperalgesia
SNL
spinal nerve ligation
SRD
subnucleus reticularis dorsalis
SRT
spinoreticular tract
SSRI
selective serotonin reuptake inhibitor
STT
spinothalamic tract
UBD
urinary bladder distension
v-STT
ventral spinothalamic tract
VI
variable interval
VMR
visceromotor reflex
VP
vasopressin
WAY
WAY 100635
WDR
wide dynamic range
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CHAPTER 1
INTRODUCTION
1.1 The Clinical Problem
Interstitial cystitis (IC) is clinically defined as “an unpleasant sensation (pain,
pressure, discomfort) perceived to be related to the urinary bladder, associated with lower
urinary tract symptoms of more than six weeks duration, in the absence of infection or
other identifiable causes” (Hanno & Dmochowski, 2009). Pain is the hallmark feature of
IC. It may be experienced in the suprapubic region, throughout the pelvis, as well as the
lower back and abdomen, and it may be associated with bladder filling, voiding, or both
(FitzGerald, Kenton, & Brubaker, 2005; Tincello & Walker, 2005; Warren et al., 2008).
In addition, patients describe a sense of an urgent need to urinate and/or an increased
frequency of urination that is distinguished from overactive bladder syndrome (Diggs et
al., 2007; Hanno, Burks, et al., 2011). The patient population disproportionately favors
women, with reports of worsening symptoms during menstruation (Powell-Boone et al.,
2005). Similar diagnoses include painful bladder syndrome (PBS), which is
characterized as suprapubic pain that is related to bladder filling, and bladder pain
syndrome (BPS), defined as chronic pelvic pain, pressure, or discomfort that is related to
the bladder and has accompanying symptoms of urgency, frequency, or both (Hanno,
Nordling, & Fall, 2011). Patients generally fall into one of two categories: Type I- those
with submucosal petechial hemorrhages (glomerulations) and Type II- those with
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Hunner’s ulcers with or without glomerulations (Buffington, 2004). There is much
overlap in the definitions of IC, PBS, and BPS, and they are often used interchangeably.
For simplicity, all references to these bladder syndromes will be referred to as IC
throughout this document.
The impact of IC carries a heavy burden on our society. The National Institute for
Diabetes, Digestive, and Kidney Diseases reported in 2000 that IC accounted for 4.1
million outpatient and clinic visits. The prevalence of IC has only grown since then. In
2009, between 3.4% and 7.8% of women in the United States were reported to be
affected (Berry et al., 2011).
While the etiology of IC is largely unknown, a critical finding among IC patients
is the correlation of stress and anxiety with exacerbation of symptoms. In laboratory
experiments, acute or chronic stress has been shown to increase the response to visceral
pain. Similarly, stress leads to exacerbation of symptoms in painful conditions of
visceral organs such as IC (Klausner & Steers, 2004; Larauche et al., 2008). In a
population-based study of over 2300 participants, patients with IC were over 4 times
more likely to have an anxiety disorder than matched controls (Chung, Liu, Lin, &
Chung, 2014). Stress or anxiety is said to have a nocebo effect- that is, the anxiety
increases the perception of pain. Physicians often try to decrease pain perception through
behaviors that decrease anxiety (Erickson et al., 2009). In fact, stress reduction is in Tier
1 of clinical guidelines aimed to treat IC (Hanno, Burks, et al., 2011).
Treatment options for patients are lacking, and treatments in current use are only
efficacious in subpopulations of IC patients. While descending modulation of bladder
pain has been the subject of numerous studies (especially involving the opioid system
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(Heinricher, Tavares, Leith, & Lumb, 2009; Porreca, Ossipov, & Gebhart, 2002; Ren &
Dubner, 2002; Stamford, 1995), fewer investigations have examined the role of
modulation involving monoamine systems, and no reports exist on serotonergic
involvement in stress-induced bladder hypersensitivity.
1.2 Purpose
Stress and anxiety appear to contribute largely to the pain experienced by patients
who suffer from IC. However, only a small fraction of IC-related research is devoted to
studying the impact of stress on bladder hypersensitivity. Reports in the literature point
to 5-hydroxytryptamine (serotonin; 5-HT) as a key modulator in chronic pain (Bardin,
2011; Cirillo, Vanden Berghe, & Tack, 2011; Crowell, 2004; Phillips & Clauw, 2011),
though there remains a gap in our knowledge of 5-HT involvement in IC or stressinduced bladder hypersensitivity. The purpose of the current set of studies is to begin a
line of research to elucidate the role of 5-HT in stress-induced bladder hypersensitivity.
This research will aim to address two main questions: (1) What is the effect of 5-HT on
stress-induced bladder hypersensitivity, and (2) what is the effect of stress on levels and
metabolism of 5-HT?
1.3 Hypotheses and Specific Aims
The general hypothesis proposed in this thesis is as follows:
Chronic stress leads to exacerbation of urinary bladder hypersensitivity, which is
facilitated by an upregulation of serotonergic activity in the spinal cord dorsal horn.
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The following sub-hypotheses expound on this hypothesis:
1. Activation of spinal serotonergic receptors, 5-HT1A and 5-HT3, facilitates the
chronic stress-induced increase in the visceromotor reflex (VMR) response to urinary
bladder distension (UBD).
2. Chronic stress leads to an increase in spinal and cerebrospinal fluid (CSF) content of
5-HT as well as an increase in the rate of 5-HT turnover.
3. Activation of spinal receptors, 5-HT1A and 5-HT3, amplifies activity of Type II
dorsal horn neurons in response to UBD.
Specific Aims formed to address these hypotheses are as follows:
Specific Aim 1: To determine the role of spinal serotonergic receptors, 5-HT1A and 5HT3, in chronic footshock stress-induced augmentation of VMR responses to UBD.
Data collected in this Aim will address the following question:
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What are the effects of spinal administration of specific 5-HT receptor antagonists
on stress-induced exacerbation of reflex responses to UBD?
Specific Aim 2: To quantitatively determine whether chronic footshock stress increases
5-HT levels in the lumbosacral spinal cord and CSF.
Data collected in this Aim will address the following questions:
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What are normal levels of 5-HT in the CSF and lumbosacral spinal cord?
•
How does chronic footshock stress affect the 5-HT levels and rate of turnover?
Specific Aim 3: To determine the role of serotonergic receptors, 5-HT1A and 5-HT3, in
the response of spinal dorsal horn neurons to UBD in chronically stressed rats.
Data collected in this Aim will address the following questions:
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•
What is the effect of chronic footshock stress on response properties of Type II
spinal dorsal horn neurons?
•
What are the effects of specific serotonergic receptor antagonists on the responses
of Type II spinal dorsal horn neurons to bladder distension in chronically stressed
rats with intact nervous systems?
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CHAPTER 2
BACKGROUND
2.1 Pain: Physiology and Modulation
2.1.1 Transmission of Pain
Pain receptors, or nociceptors, are specialized peripheral nerve endings that
respond to noxious stimuli, including temperature extremes, intense pressure, and
chemicals. Thus, nociceptors are of three main types: thermal, mechanical, and chemical.
If a nociceptor responds to more than one type of noxious stimulus, it is referred to as a
polymodal nociceptor. For example, mechanoheat nociceptors respond to painful thermal
and mechanical stimulation. Silent nociceptors are those which are generally insensitive
to intense stimuli but which become responsive under conditions of inflammation or
injury.
Transmission of nociceptive signals, or action potentials, occurs along axons of
these sensory neurons. A-δ fibers are medium diameter, myelinated primary afferents
that are rapidly-conducting. Nociceptive information transmitted along A-δ fibers is
therefore perceived quickly, and the pain is well-localized and often described as instant
and sharp. C-fibers are small diameter, unmyelinated primary afferents that conduct
action potentials more slowly. As a consequence, pain is perceived a second or more
after the stimulus is applied and gradually increases in intensity. It is more generalized
and is often described as dull, achy, throbbing, and burning.
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These afferent nerve fibers synapse onto the dorsal root ganglia of the spinal cord,
where their signals can be transmitted further to other spinal regions or to the brain.
Specifically in the dorsal horn of the spinal cord, two classes of pain-signaling neurons
exist. Nociceptive specific (NS) neurons elicit action potentials only in response to
painful stimuli; thus NS cells receive input exclusively from A-δ and C-fibers. In
contrast, wide dynamic range (WDR) neurons are responsive to noxious and non-noxious
stimuli. WDR neurons also synapse with large diameter, highly myelinated A-β fibers, in
addition to A-δ and C-fibers. A-β fibers generally convey information about light touch
or other innocuous peripheral stimulation. Consequently, WDR neurons are more
sensitive to stimulus intensity than their NS counterparts (Dickenson & Sullivan, 1987).
Following integration in the dorsal horn, nociceptive information is transmitted to
supraspinal sites via ascending pain pathways. The spinothalamic tract (STT) is the major
ascending pain pathway, with projections leading to the thalamus. The STT has two
main divisions: the lateral or neospinothalamic tract (l-STT) and the ventral or
paleospinothalamic tract (v-STT). The l-STT projects to posterior thalamic nuclei and is
thought to be involved in spatial and temporal discrimination of pain and touch (Price &
Dubner, 1977). The v-STT projects to medial and intralaminar thalamic nuclei and is
considered integral to aversive motivational processing (Holloway, Fox, & Iggo, 1978;
Kerr, 1975; Price, Hayes, Ruda, & Dubner, 1978). The spinoreticular tract (SRT) has
common projections terminating in the reticular formation. The majority of SRT
projections encode information pertaining to innocuous stimuli, although the nucleus
reticularis gigantocellularis (NGC) of the reticular formation is an important nucleus for
nociceptive processing (Collins & Randt, 1960). The reticular formation has further
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projections to the thalamus, hypothalamus, and limbic structures (Casey, 1969). Cortical
areas involved in pain processing include a distribution which is considered the “pain
matrix” (Ingvar, 1999). These areas include the anterior cingulate cortex (ACC), insula,
frontal cortex, amygdala, and somatosensory cortices I and II (Ingvar, 1999; Jones, 1992;
Peyron, Laurent, & Garcia-Larrea, 2000; Talbot et al., 1991). Somatosensory cortices are
thought to process information relating to location and intensity (Bushnell et al., 1999;
Kanda et al., 2000), and the ACC is said to process the affective component of
nociception (Rainville, Duncan, Price, Carrier, & Bushnell, 1997). Finally, the insula is
thought to be involved in encoding information pertaining to intensity, laterality, and
affective components of pain (Brooks, Nurmikko, Bimson, Singh, & Roberts, 2002;
Coghill, Sang, Maisog, & Iadarola, 1999; Singer et al., 2004).
Cutaneous pain and visceral pain are, to an extent, processed separately in the
central nervous system (CNS). This is important for the strong emotional responses that
can be evoked by visceral pain (Traub, Silva, Gebhart, & Solodkin, 1996). The brain’s
response to pain is generally thought to be through spinal inhibition of afferent signals
produced mostly by endogenous opioids and, to a lesser degree, other neurotransmitters.
2.1.2 Descending Modulation of Pain
Descending modulation of pain can be inhibitory or facilitatory in action (Zhuo &
Gebhart, 1990, 1992, 1997). Initial reports of descending inhibition resulted from
stimulation of the periaquaductal gray (PAG), which produced antinociception sufficient
to perform laparoscopic surgery in rats (Reynolds, 1969). Motor responses were
unaffected, and responses to nociceptive stimuli returned following the termination of
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electrical stimulation (Reynolds, 1969). It was later discovered that microinjections of
opiates, including morphine, into the PAG produced similar analgesia that was reversed
by naloxone (Cheng, Fields, & Heinricher, 1986; Kosterlitz & Hughes, 1977; Llewelyn,
Azami, & Roberts, 1986). Both electrical stimulation and drug administration into the
PAG showed tolerance and cross-tolerance to each other, demonstrating endogenous
opioid pain control (Hughes, 1975; Mayer & Hayes, 1975). Stimulation-produced
analgesia from the PAG can be blocked completely or partially by lesioning sites in the
rostroventral medulla (RVM), indicating the RVM as the output center in descending
pain controls (Porreca et al., 2002). Stimulation of the RVM itself produces inhibition,
facilitation, or intensity-dependent biphasic effects on nociceptive processing (Millan,
1999; Urban & Gebhart, 1999). Lower intensities of electrical stimulation produce
facilitation, whereas higher intensities produce more inhibition (Zhuo & Gebhart, 1997).
These findings were reproduced using glutamate stimulation of the RVM (Zhuo,
Sengupta, & Gebhart, 2002). Furthermore, electrical stimulation of the nucleus raphe
magnus (NRM) decreased the responsiveness of dorsal horn neurons to noxious heat
applied to the tail of the rat (Llewelyn et al., 1986). Other sites within the RVM that
produce stimulation-induced pain inhibition, facilitation, or both include the NGC, NGC
pars α, nucleus raphe obscuris, and nucleus raphe pallidus. In studies of bladder
hypersensitivity, stimulation of the RVM produced predominant inhibition of the VMR to
UBD (Randich, Mebane, DeBerry, & Ness, 2008). Stimulation of the RVM also
produced site- and intensity-dependent facilitation of the VMR to UBD but to a lesser
extent than inhibition (Randich, Mebane, et al., 2008).
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During electrophysiological recording in the RVM, Fields et al. (1983), found that
populations of neurons responded differentially to the tail flick reflex, a nociceptive test
in rodents that measures the time to withdraw the tail from a noxious radiant heat source
(D'amour & Smith, 1941). Some neurons abruptly stopped firing prior to withdrawal of
the tail from the heat source, while others abruptly or gradually started firing just before
the tail withdrawal. These were named on-cells and off-cells, respectively. Another
subset of neurons demonstrated no change in response to tail flick and were termed
neutral-cells (Fields, Bry, et al., 1983). All on-cells are excited by noxious pinch of the
skin, while most off-cells are inhibited by pinch (Fields, Bry et al. 1983). Micro-injection
of morphine or cannabinoid CB1 receptor agonist, WIN-55,212-2, into the RVM
extinguished on-cell firing, off-cell cessation, and tail withdrawal in the tail flick test
(Meng & Johansen, 2004). Both on- and off-cells are excited by electrical stimulation of
the PAG (Fields, Vanegas, Hentall, & Zorman, 1983). Heinricher et al. (1989),
discovered through simultaneous recordings of RVM neurons that neurons of the same
class (i.e. on- or off-) are all active at the same time, and these periods of activity
alternate with the opposing class. This is one line of evidence that supports the
conclusion that on- and off-cells play reciprocal roles, and that off-cells are inhibitory of
on-cells. Further support is that off-cells discontinue their activity just prior to
withdrawal reflexes such as the tail flick and the onset of activity of thalamic neurons in
response to noxious stimulation (Hernández, López, & Vanegas, 1989). In addition, only
off-cells become active upon systemic or PAG administration of morphine, while
morphine causes on-cells to become quiescent (Barbaro, Heinricher, & Fields, 1986;
Cheng et al., 1986; Fields, Vanegas, et al., 1983).
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As far as which neurotransmitters are involved in on-/off-cell function, less is
known. It has been suggested that the off-cell pause is influenced by activation of γaminobutyric acid (GABA)-A receptors (Heinricher & Kaplan, 1991). On-cells are
GABA-containing and most likely inhibit off-cells during noxious stimulation
(Heinricher & Tortorici, 1994). The RVM is rich in serotonergic cells, but it is unclear
whether any of these are on- or off-cells (Geranton, Fratto, Tochiki, & Hunt, 2008;
Ossipov, Dussor, & Porreca, 2010; Porreca et al., 2002; Rahman, Suzuki, Webber, Hunt,
& Dickenson, 2006; Suzuki, Morcuende, Webber, Hunt, & Dickenson, 2002; Suzuki,
Rygh, & Dickenson, 2004). Interestingly, about 50% of neutral-cells stain positive for 5HT (Potrebic, Fields, & Mason, 1994). Other reports indicate a potential role for
norepinephrine (NE) in modulating on- and off-cell activity. NE-containing fibers and
terminals have been identified throughout the RVM (Dahlstrom & Fuxe, 1964; Fuxe,
Hökfelt, & Ungerstedt, 1969). Microinjection of the α2 receptor agonist, clonidine,
resulted in an increase of the tail flick latency and produced long-lasting inhibition of oncell firing (Fields, Heinricher, & Mason, 1991).
2.1.3 Diffuse Noxious Inhibitory Control
Diffuse noxious inhibitory control (DNIC) describes processes in which a
hyperalgesic response to a noxious stimulus is inhibited by the application of another
noxious stimulus to a spatially-distinct receptive field (Dickenson, Rivot, Chaouch,
Besson, & Le Bars, 1981). DNIC is mediated through a spino-bulbo-spinal pathway with
ascending transmission from the ventrolateral spinal cord to supraspinal areas and
descending through the dorsolateral funiculi to the spinal cord dorsal horn (Bouhassira,
11
Chitour, Villanueva, & Le Bars, 1993; Le Bars & Villanueva, 1988; Roby-Brami, Bussel,
Willer, & Le Bars, 1987). DNIC relies on an intact nervous system, and is therefore
presumed to be mediated by supraspinal structures (Le Bars, Dickenson, & Besson, 1979;
Morton, Maisch, & Zimmermann, 1987). Lesions of brainstem nuclei such as PAG,
RVM, locus coeruleus (LC), and parabrachial nucleus have no effect on DNIC
(Bouhassira, Bing, & Le Bars, 1990; Bouhassira et al., 1993). However, DNIC is
abolished by lesioning the subnucleus reticularis dorsalis (SRD; (Bouhassira, Villanueva,
Bing, & le Bars, 1992; Villanueva, Bouhassira, & Le Bars, 1996). This finding, along
with others that the SRD is favorably activated by nociceptive stimuli and has descending
projections to the spinal cord dorsal horn, suggests that the SRD is a crucial structure for
DNIC processing (Bernard, Villanueva, Carroue, & Le Bars, 1990; Villanueva et al.,
1996).
Peripherally, responses are inhibited by noxious stimulation of A-δ or C-fibers
(Villanueva & Le Bars, 1985). Centrally, DNIC is dependent on an ascending and
descending loop through ventro- and dorso-lateral funiculi (Villanueva, Chitour, & Le
Bars, 1986). Pharmacological mediation of DNIC is still under investigation, although
some reports indicate involvement of serotonergic and opioid systems. Nociceptive
inhibition produced by DNIC is significantly reduced by systemic blockade of 5-HT
receptors and is augmented after administration of the 5-HT precursor, 5hydroxytryptophan (5-HTP) (Chitour, Dickenson, & Le Bars, 1982). Opioidergic
modulation of DNIC is less clear. Low dose morphine is said to decrease inhibition
brought on by DNIC, which is reversed by naloxone (Le Bars, Villanueva, Bouhassira, &
12
Willer, 1992; Willer, Le Bars, & De Broucker, 1990). On the other hand, administration
of naloxone alone has no effect on DNIC (Edwards, Ness, & Fillingim, 2004).
Dysfunction of DNIC has been observed in populations of patients with
functional disorders such as irritable bowel syndrome and fibromyalgia (Lautenbacher &
Rollman, 1997; Wilder-Smith, Schindler, Lovblad, Redmond, & Nirkko, 2004). A
dysfunction of DNIC has also been reported in patients with IC (Ness, Lloyd, &
Fillingim, 2014). Alterations in DNIC function suggest an imbalance in nociceptive
facilitation and inhibition.
2.2 Stress: Physiology and Role in Pain Perception
2.2.1 Physiology of Stress Response
2.2.1.1 Hypothalamic-Pituitary-Adrenal Axis. The body’s reaction to stress is
mediated in part by the hypothalamic-pituitary-adrenal (HPA) axis. The role of the HPA
axis is ultimately to increase glucocorticoid secretion, which, in turn, increases
catecholamine secretion. The anatomical pathway of the HPA axis is from the medial
parvocellular region of the paraventricular nucleus (PVN) of the hypothalamus to the
corticotrope cells of the anterior pituitary to the zona fasciculata cells of the adrenal
cortex, which send negative feedback information to the hypothalamus and anterior
pituitary. During times of stress, neurosecretory cells from the PVN secrete
corticotropin-releasing factor (CRF), a 41 amino acid peptide hormone, onto capillaries
of the median eminence that penetrate the anterior pituitary. In the anterior pituitary,
binding of CRF to the CRF type 1 receptor (CRFR1) stimulates the release of
adrenocorticotropic hormone (ACTH; 39 amino acids; (Aguilera, Rabadan-Diehl, &
13
Nikodemova, 2001). Vasopressin (VP), a 9 amino acid peptide hormone, has also been
shown to stimulate the release of ACTH from the anterior pituitary. CRF$increases$
transcription$of$proopiomelanocortin$(POMC),$a$precursor$to$ACTH,$as$well$as$
increases$cyclic adenosine monophosphate/protein kinase A (cAMP/PKA)$to$increase$
ACTH$release$from$cells.$ In$addition,$VP,$acting$at$VP1$receptors$causes$the$release$
of$ACTH$from$multiple$cells$(Levin, Blum, & Roberts, 1989).
ACTH released from the anterior pituitary binds to ACTH receptors on the
surface of adrenocoritical cells of the zona fasciculata. Binding of the receptor leads to
activation of PKA, which phosphorylates cholesterol esterase and steroidogenic acute
regulatory protein, both of which lead to synthesis of the glucocorticoid, cortisol in
humans and corticosterone in rodents and many non-mammals. Cortisol is involved in
numerous physiological activities, including: stimulation of gluconeogenesis in the liver
to increase blood glucose, stimulation of glycogenesis to increase glycogen in the liver,
promotion of protein catabolism in skeletal muscle to provide an energy source (amino
acids) for gluconeogenesis, promotion of fat catabolism also to provide an energy source
(glycerol) for gluconeogenesis, induction of phenylethanolamine-N-methyltransferase
(PNMT) to synthesize catecholamines, and suppression of the immune response.
Completing the HPA cycle, glucocorticoids inhibit the release of CRF from the
hypothalamus (Sakakura, Yoshioka, Kobayashi, & Takebe, 1981).
Glucocorticoids, such as cortisol or corticosterone, released from the adrenal
cortex exert negative feedback on CRF and ACTH. Two classes of glucocorticoid
receptors are located throughout the brain. Type I, cortisol/corticosterone receptors, are
found primarily in limbic neurons, while Type II receptors are found throughout the
14
hypothalamus (McEwen, 1994). Type I receptors respond mainly to emotional and
environmental stimuli, while Type II receptors have a strong affiliation with the negative
feedback effects of cortisol (Sapolsky, Krey, & McEwen, 1986)
CRF is also present in neurons outside of the hypothalamus in brainstem,
midbrain, limbic areas, cerebral cortex, and spinal cord (De Souza et al., 1985). CRF is
regulated by factors such as pain, emotion, and blood pressure. In particular, an increase
in blood pressure exerts an inhibitory response on CFR secretion, while a decrease in
blood pressure results in higher levels of CRF secretion (Ganong, 1988). CRF is also
stimulated by NE and E, acetylcholine, and serotonin. CRF secretion is inhibited by
neurotransmitters such as GABA, opioids, ACTH, and glucocorticoids (Calogero,
Bernardini, Gold, & Chrousos, 1988).
.
2.2.1.2 LC-NE/Sympatho-Medullary Systems. The LC-NE/sympathetic systems
represent the principal autonomic response to external stress. The LC is the primary
source of NE-producing neurons in the brain with effects of arousal and increased anxiety
(Shimizu, Katoh, Hida, & Satoh, 1979). Sympathetic activation results in release of NE
from the adrenal medulla, and is typically advantageous to the organism in a stressful
situation. Sympatho-medullary NE and E generally stimulate the regulation of
catecholamine biosynthesis (Landsberg & Weiss, 1976; McCarty, 1983). This is
demonstrated in the studies showing that acute stress results in an increase in secretion of
sympatho-medullary NE and E, while chronic stress results in increased catecholamine
synthesis and catecholamine concentrations in rat blood (Dobrakovova et al., 1984;
Tilders & Berkenbosch, 1986).
15
2.2.2 Models of Laboratory Stress
Stress may be categorized as physical or psychological. Physical (extereoceptive;
systemic) stress is induced by stimuli that produce actual physical perturbations which
offset homeostasis. Psychological (interoceptive; neurogenic; processive) stress is
elicited by stimuli that compromises the organism’s perceived or anticipated state (Dayas,
Buller, Crane, Xu, & Day, 2001; Herman & Cullinan, 1997). Stressors may be further
classified as acute or chronic depending on the temporal presentation of the stimuli. An
acute stressor is presented one time, while a chronic stressor is usually presented for 7-10
days consecutively. Purely physical stressors include the following: cold water
immersion, in which rats are placed in a tank of cold water without the ability to escape
for 15 min; cold environment, in which rats are placed in a 4°C cold room for 15 min;
hemorrhage, in which a total of around 12 ml/kg of blood is removed; and immune
challenge, in which a pro-inflammatory cytokine such as interleukin-1β is injected to
induce an inflammatory response (Dayas et al., 2001; Jaggi et al., 2011). Purely
psychological stressors include the following: maternal separation, in which rat pups are
separated from their dams each day for around 3 h; predatory stress, in which an animal
is exposed to its natural predator or the scent of the predator; social defeat, in which an
“intruder” rat is placed into a cage of “resident” rats until the intruder displays
subordinate postures; water avoidance, in which rats are placed on a small platform
surrounded by water on all sides; and noise stress, in which the animal is exposed to
aversive auditory stimuli such as white noise (Campos et al., 2013; Dayas et al., 2001;
Jaggi et al., 2011). Both physical and psychological stressors have been shown to
16
activate neurons in the PVN, while physical stress preferentially activates the central
amygdala and psychological stress preferentially activates the medial amygdala (Dayas et
al., 2001).
A subset of stress models are not consistently labeled as physical or
psychological, and thus they are labeled as mixed physical-psychological. Mixed
stressors include the following: forced swim, in which rats are placed in a cylindrical tank
filled with water to require swimming; restraint stress, in which animals are placed in a
conical or cylindrical tube or their limbs are taped to a surgical board to immobilize the
animal; and footshock stress, in which animals are placed on an electrified floor-grid that
delivers mild electrical shock at variable intervals (VI; (Dayas et al., 2001; Jaggi et al.,
2011; Kant, Mougey, Pennington, & Meyerhoff, 1983). The current experimental
procedures employ chronic footshock to induce stress in the rat. Footshock is considered
a mixed paradigm due to the physical component of electrical shock and the
psychological component of unpredictability in the timing of the shocks. Stress
paradigms typically must demonstrate activation of the HPA axis to ensure that the
stimulus is indeed inducing a stress response (Bodnar, Glusman, Brutus, Spiaggia, &
Kelly, 1979; Bonaz & Tache, 1994; Kant et al., 1983). Kant et al. (1983) demonstrated
that footshocks ranging from 0.2-3.2 mA delivered to rats on a VI schedule produced
increased plasma stress-related hormones, including corticosterone and beta-endorphin.
2.2.3 Stress as an Analgesic
Historically, acute stress elicits a fight or flight response. In this situation,
nociceptive processes are blunted, allowing the organism to respond in the most adaptive
17
manner. Indeed, if an animal had to stop to attend to an injured limb while in pursuit, it
would most likely fall prey to its predator. The first studies of stress-induced analgesia
(SIA) reported an increase in pain threshold to a cutaneous noxious stimulus after
inescapable footshock that was not always reversible by naloxone administration (Hayes,
Price, Bennett, Wilcox, & Mayer, 1978). Neurotransmitter systems involved in SIA
typically include glutamate, GABA, glycine, vasopressin, oxytocin, opioids, and
cannabinoids (Butler & Finn, 2009; Marek, Mogil, Sternberg, Panocka, & Liebeskind,
1992). The HPA axis also plays a role in SIA; hypophysectomized rats demonstrated a
reversal of cold water swim SIA (Bodnar et al., 1979).
2.2.4 Stress as an Exacerbator of Pain
In contrast to SIA, stress-induced hyperalgesia (SIH) occurs in response to stress
that is particularly unpredictable and uncontrollable. In this case, pain is augmented
instead of inhibited. Indeed, stress has been shown to increase nociceptive responses in
animal models of visceral pain. Clinically, stress leads to exacerbation of symptoms in
irritable bowel syndrome, IC, and other chronic visceral pain disorders (Dickhaus et al.,
2003; Klausner et al., 2005; Larauche, Kiank, & Tache, 2009). Chronic footshock stress
induces urinary bladder hypersensitivity characterized by an increase in the VMR
response to UBD (Robbins & Ness, 2008). Chronic water avoidance stress also induced
hyperresponsive electromyographic (EMG) activity to UBD (Robbins, DeBerry, & Ness,
2007). In colorectal pain studies, chronic water avoidance stress enhanced EMG
responses to colorectal distension (CRD; (Bradesi et al., 2005; Hong et al., 2009; Wang et
al., 2013). Furthermore, using cerebral blood flow mapping, stressed rats showed greater
18
activation of insular cortex, amygdala, and hypothalamus and less activation in the
prelimbic area of prefrontal cortex evoked by CRD. Stressed rats lacked the negative
correlation found between the prelimbic area and the amygdala, which was found in sham
rats (Wang et al., 2013). Chronic variant stress using the paradigm of alternating cold,
restraint, water avoidance, or forced swim daily for 9 days produced colorectal
hypersensitivity (Winston, Xu, & Sarna, 2010). It would appear that clinical populations
and animal models alike have an increased sensitivity to chronic stress resulting in
enhanced visceral nociception.
2.3 Serotonin: Physiological Function and Role in Stress and Pain Systems
2.3.1 Serotonergic Receptors/Function
2.3.1.1 Overview. Seven receptor families comprise the receptors with affinity
for the monoamine, 5-HT. This section will discuss the location, function, and
mechanism of action of each receptor subtype. Nevertheless, this is far from being an
exhaustive list, as that would extend beyond the scope of this report (for review see
Barnes & Sharpe, 1999).
The seven families are categorized by mechanism of action and/or G-protein
coupling. The 5-HT1 receptors are coupled to the Gi/Go protein, and activation leads to
a decrease in cAMP production. 5-HT2 receptors are coupled to the Gq11 protein.
Activation of 5-HT2 leads to an increase in inositol triphosphate and diacyl glycerol,
enhancing protein phosphorylation and excitatory neurotransmission. The 5-HT3
receptor is the only ionotropic receptor of the 5-HT super family of receptors, and its
activation leads to an excitatory neuronal response. Receptors 5-HT4, 5-HT6, and 5-HT7
19
are Gs-protein coupled, and produce an excitatory response by increasing levels of
cAMP. The 5-HT5 receptors are coupled to the Gi/Go protein. Activation leads to an
inhibitory response via a decrease in cAMP.
2.3.1.2 5-HT1A. The 5-HT1A receptor is the most widespread, encompassing
areas in the cortex, hippocampus, amygdala, raphe nucleus, basal ganglia, and thalamus,
and it has a diverse range of functions (Glennon et al., 2000; Ito, Halldin, & Farde, 1999).
Activation of 5-HT1A receptors in the RVM produces a decrease in blood pressure and
heart rate via peripheral vasodilation. Vagal nerve stimulation through 5-HT1A
activation also contributes to these vascular effects (Dabire, 1991). Mood disorders such
as anxiety and depression show a reduction with receptor activation (Kennett, Dourish, &
Curzon, 1987; Parks, Robinson, Sibille, Shenk, & Toth, 1998). In addition, antiemetic
and analgesic effects are observed with activation of 5-HT1A receptors in the dorsal
raphe nucleus that are colocalized with neurokinin 1 receptors, modulating the release of
substance P (Baker et al., 1991).
5-HT1A activation enhances dopamine release within the medial prefrontal
cortex, striatum, and hippocampus (Bantick, De Vries, & Grasby, 2005; Li, Ichikawa,
Dai, & Meltzer, 2004). Conversely, stimulation inhibits the release of glutamate and
acetylcholine, temporarily impairing learning and memory (Ogren et al., 2008). On the
endocrine level, activation induces the secretion of HPA-axis hormones, including
cortisol/corticosterone and ACTH, as well as oxytocin, prolactin, and β-endorphin
(Koenig, Gudelsky, & Meltzer, 1987; Lorens & Van de Kar, 1987; Pitchot, Wauthy,
Legros, & Ansseau, 2004).
20
In addition to the multitude of physiological effects of 5-HT1A receptor
activation, its role as an autoreceptor is equally as important. In this respect, 5-HT1A
receptors located on 5-HT-releasing neurons inhibit further release of 5-HT. The action
of 5-HT1A autoreceptors is reported to be a large contributing factor in the therapeutic
lag of selective serotonin reuptake inhibitors (SSRI). The autoreceptors must become
desensitized to allow an increase in extracellular 5-HT (Hjorth et al., 2000).
2.3.1.3 5-HT1B. Receptors of the 5-HT1B class are located throughout the brain,
mainly in frontal cortex, basal ganglia, striatum, and hippocampus, as well as within
blood vessels (Hen, 1993; Maroteaux et al., 1992; Martin et al., 1997). In the CNS,
activation is attributed to diminished release of dopamine and glutamate (Huang, Yeh,
Wu, & Hsu, 2013). The more prominent role of 5-HT1B receptors appears to be in
vasoconstriction. Agonists of 5-HT1B include various triptan drugs and ergotamine
which exert powerful vasoconstricting effects used in the treatment of migraine
headaches.
2.3.1.4 5-HT1D. 5-HT1D receptors are predominantly expressed in basal ganglia
but also in blood vessels (Cubero et al., 2011; Domenech, Beleta, & Palacios, 1997;
Longmore et al., 1997). Activation of central 5-HT1D receptors presynaptically inhibits
synaptic transmission, contributing to modulation of locomotion (Schwartz,
Gerachshenko, & Alford, 2005). Like the 5-HT1B agonists, those of 5-HT1D are also
involved in the mitigation of migraine pain via vasoconstriction.
21
2.3.1.5 5-HT1E. Putative 5-HT1E receptors are located in the frontal cortex,
hippocampus, and olfactory bulb (Bai et al., 2004). While their function has yet to be
elucidated, theories include involvement in the improvement of learning and memory
(Brudeli et al., 2010).
2.3.1.6 5-HT1F. Most closely related to 5-HT1E, the 5-HT1F receptor shares a
70% sequence homology (Barnes & Sharp, 1999). 5-HT1F receptors are located in the
dorsal raphe, hippocampus, cortex, striatum, thalamus, and hypothalamus (Cubero et al.,
2011). 5-HT1F is targeted by sumatriptan, suggesting a possible role in migraine
treatment (Hamon & Bourgoin, 2000; Waeber & Moskowitz, 1995).
2.3.1.7 5-HT2A. The 5-HT2A receptor is highly expressed in cortical brain
regions, especially in layer V pyramidal cells (Aghajanian & Marek, 1999). Receptors
are also observed in blood vessels, and particularly in platelets, where activation
promotes platelet aggregation and vasoconstriction (Gomez-Gil et al., 2002). The 5HT2A subtype is highly associated with the effects of psychedelic drugs such as lysergic
acid diethylamide (LSD), mescaline, and psilocybin (McCorvy, Harland, Maglathlin, &
Nichols, 2011). Antagonism of 5-HT2A is the target of many antipsychotic medications
(Seeman, 2002).
2.3.1.8 5-HT2B. 5-HT2B receptors are located in cerebellum, lateral septum,
hypothalamus, and medial amygdala (Duxon et al., 1997). These receptors play a pivotal
role in cardiovascular function. The receptor is critical for proper cardiac development as
22
demonstrated by a knock-out mouse model (Nebigil, Etienne, Messaddeq, & Maroteaux,
2003). In the periphery, activation of vascular 5-HT2B receptors stimulates pulmonary
vasoconstriction (Launay et al., 2002). There is a strong implication of 5-HT2B receptor
activation in valvular heart disease induced by the use of the weight-loss drug
fenfluramine (Connolly et al., 1997). In the CNS, activation of receptors may induce
psychedelic behavioral effects with drugs such as 3,4-methylenedioxy-Nmethylamphetamine (MDMA; (Doly et al., 2008).
2.3.1.9 5-HT2C. One of the most ubiquitous 5-HT receptors, 5-HT2C is located
in the brain in the prefrontal cortex, striatum, nucleus accumbens, hippocampus,
hypothalamus, and amygdala (Pompeiano, Palacios, & Mengod, 1994). In the periphery,
receptors have been shown in blood vessels, platelets, gastro-intestinal (GI) tract, and
smooth muscle. 5-HT2C receptors perform an important function in the regulation of
mood, feeding, and reproduction (Heisler et al., 2007). Mood regulation is generally
achieved through antagonism of 5-HT2C receptors (Berg, Harvey, Spampinato, &
Clarke, 2005; Ni & Miledi, 1997). 5-HT2C activation by SSRIs also contributes to the
therapeutic lag since the receptors must downregulate over the first 1-2 week period to
achieve the desired antidepressive effects (Berg et al., 2005). Many drugs of addiction,
including cocaine, opiates, caffeine, and nicotine, exert antagonistic properties on
5-HT2C receptors, increasing the release of dopamine, therefore contributing to drug
reinforcement (Bubar & Cunningham, 2006). In the paraventricular nucleus, activation
of 5-HT2C receptors is responsible for the increased release of CRF and vasopressin
(Heisler et al., 2007).
23
2.3.1.10 5-HT3. Expression of the 5-HT3 receptor has been shown extensively
throughout the central and peripheral nervous system (Yakel & Jackson, 1988). The
major function of the 5-HT3 receptor is its mediation of emesis, specifically by
enhancing the emetic effects of radiation and chemotherapy. Consequently, antagonists
of 5-HT3 receptors are used for their antiemetic effects (Thompson, 2013).
2.3.1.11 5-HT4. 5-HT4 receptors are located within the GI tract, peripheral
nervous system, and brain areas, including basal ganglia, raphe, pontine nuclei, and
thalamus (Varnas, Halldin, Pike, & Hall, 2003). 5-HT4 activation increases GI motility
by stimulating acetylcholine release (Martin & Humphrey, 1994). Additionally, it has
been hypothesized that 5-HT4 activation enhances memory performance via increased
synaptic transmission within the CNS (Barnes & Sharp, 1999).
2.3.1.12 5-HT5A. Little is known about the location and function of 5-HT5A
receptors, although expression has been demonstrated on astrocytes and specific motor
neurons (Carson, Thomas, Danielson, & Sutcliffe, 1996; Xu et al., 2007). Regulation of
sleep has been reported through 5HT5A agonism via valerenic acid (Dietz, Mahady,
Pauli, & Farnsworth, 2005).
2.3.1.13 5-HT6. The 5-HT6 receptor is restricted to, yet widely distributed
throughout, the brain (Gerard et al., 1997; Kohen et al., 1996; Woolley, Marsden, &
Fone, 2004). Antagonism of the receptor increases the release of excitatory
24
neurotransmitters, including glutamate, acetylcholine, dopamine, and NE (Dawson,
Nguyen, & Li, 2000, 2001; Lacroix, Dawson, Hagan, & Heidbreder, 2004). Antagonists
provide the greatest therapeutic value, ranging from improvement in learning and
memory to the treatment of obesity (Heal, Smith, Fisas, Codony, & Buschmann, 2008;
King, Marsden, & Fone, 2008). In contrast, activation of 5-HT6 receptors enhances
GABA signaling, and 5-HT6 agonists have improved mood disorders (Schechter et al.,
2008). These receptors may be a critical component in the mechanism of SSRI therapy
(Carr, Schechter, & Lucki, 2011).
2.3.1.14 5-HT7. The 5-HT7 receptor is expressed in the brain, GI tract, and
blood vessels (Bard et al., 1993). Blockade of the 5-HT7 receptor produces antipsychotic
and antidepressive effects (Mullins, Gianutsos, & Eison, 1999; Roth et al., 1994). The 5HT7 receptor has also been implicated in sleep, circadian rhythms, and thermoregulation
to a lesser degree (for review, see (Hedlund, 2009).
2.3.2 Relationship of Serotonin and Stress
Chronic stress induces changes in many neuroendocrine systems, including the
monoamines. In rats, exposure to 1h of restraint-stress for 24 days resulted in increased
brain levels of 5-HT (Adell & Artigas, 1998), and increased levels of tryptophan
hydroxylase were observed in the RVM of rats exposed to 3 weeks of restraint stress
(Imbe, Iwai-Liao, & Senba, 2006). Chronic exposure to an elevated open platform
resulted in a sustained increase in the release and turnover of 5-HT in rats (Storey et al.,
2006). These examples indicate that chronic stress leads to an increase in 5-HT
25
production, release, and turnover in the CNS. Typically lower levels of 5-HT are
associated with individuals who are severely depressed or have committed suicide. It
may be the case that especially in the early stages of chronic stress, 5-HT production and
activity are increased as a coping mechanism.
Furthermore, 5-HT facilitates stress-induced effects in rats via 5-HT1A and 5HT3 receptor activation. In a model of stress-induced colorectal pain, treatment with the
5-HT3 antagonist, alosetron, abolished visceral hypersensitivity (Bradesi et al., 2007).
Chronic stress-induced decrease in sucrose consumption was ameliorated with
administration of the 5-HT1A antagonist, WAY 100635 (Papp, Nalepa, AntkiewiczMichaluk, & Sanchez, 2002). Activation of serotonergic receptors facilitate the VMR
response to UBD in rats with zymosan-inflamed bladders (Randich, Shaffer, Ball, &
Mebane, 2008). Intrathecal administration of the non-selective 5-HT receptor antagonist,
methysergide; 5-HT1A-specific antagonist, WAY 100635; or 5-HT3-specific antagonist,
ondansetron, resulted in a decrease in the VMR response to UBD in rats pretreated with
intravesicle zymosan. These data further support a link between stress, visceral
hypersensitivity and the 5-HT1A and 5-HT3 receptors.
2.3.4 Serotonergic Pain Modulation
The role of 5-HT in nociceptive signaling is complicated; there is evidence that it
may facilitate or inhibit pain. Most 5-HT-producing cells that have projections to the
spinal cord dorsal horn are located in the rostral ventromedulla (RVM). Electrical
26
stimulation of the nucleus raphe magnus of the RVM increased latency in the tail
withdrawal to noxious heat. This effect was blocked by intrathecal administration of the
5-HT receptor antagonist, methysergide (Hammond & Yaksh, 1984), demonstrating an
inhibitory role for 5HT in nociceptive processing. Wei et al. (2010) selectively knocked
down 5-HT-producing cells in the RVM using ribonucleic acid-interference (RNAi).
Recombinant plasmids encoding for tryptophan hydroxylase 2 (Tph-2) short hairpinRNA (shRNA) were microinjected into the RVM of adult rats. Using this model, rats
were then tested for their response to the formalin test (Tjolsen, Berge, Hunskaar,
Rosland, & Hole, 1992), a nociceptive test that evaluates acute (phase 1) and persistent
(phase 2) pain. During phase 1, there was no difference in nocifensive responses between
RVM 5-HT-depleted rats and controls. On the other hand, pain behaviors were
significantly reduced during phase 2 in RVM 5-HT-depleted rats, suggesting a
facilitatory role of 5-HT, particularly in persistent pain (Wei et al., 2010). Also utilizing
RVM 5-HT-depletion, Wei et al. (2010) further assessed persistent pain in the spinal
nerve ligation (SNL) model of neuropathic pain. In control rats, SNL produced thermal
and mechanical hyperalgesia 14 d before and after gene transfer. RVM 5-HT-depleted
rats showed a significant reduction in thermal and mechanical hyperalgesia up to 7 d after
gene transfer.
Whether 5-HT is facilitatory or inhibitory may depend on which of the myriad 5HT receptors is activated. While there are at least 15 known 5-HT receptor subtypes, 5HT1A and 5-HT3 are predominant in the spinal cord and have a more defined role in
nociceptive processing (Hochman, 2001). Activation of 5-HT1A has been shown to
facilitate pain signals in the dorsal horn, possibly as an indirect or secondary mechanism
27
(Ali, Wu, Kozlov, & Barasi, 1994; Zhang et al., 2001). To illustrate this point, Song, et
al. (2007), utilized intrathecal administration of the 5-HT1A agonist, 8-Hydroxy-N,Ndipropyl-2-aminotetralin (8-OH-DPAT), which produced inhibition of mu opioid
receptor internalization, a proxy for determining mu opioid receptor activation. This was
reversed with the co-administration of 8-OH-DPAT and the 5-HT1A antagonist, WAY
100135, suggesting 5-HT1A-mediated inhibition of opioid release in the spinal cord.
Intrathecal 8-OH-DPAT also increased the responsiveness of WDR neurons to electrical
stimulation (Zhang et al., 2001).
5-HT3 receptors are located on fibers and primary afferent terminals (Kidd et al.,
1993) and have been implicated to a greater extent in nociceptive augmentation (Asante
& Dickenson, 2010; Suzuki et al., 2004). Their activation leads to the release of
substance P, calcitonin gene related peptide, and neurokinin A, all of which are involved
in inflammation and nociceptive processing (Inoue, Hashimoto, Hide, Nishio, & Nakata,
1997; Saria, Javorsky, Humpel, & Gamse, 1990). In the formalin test, intrathecal
administration of the 5-HT3 receptor antagonist, ondansetron, attenuated
hyperexcitability of dorsal horn neurons during the late phase (Svensson, Tran,
Fitzsimmons, Yaksh, & Hua, 2006). Ondansetron also attenuated neuronal responses to
mechanical stimuli in rats with spinal nerve ligation (Suzuki et al., 2004). Mice with null
5-HT3 receptors via knock-out of the A subunit of the 5-HT3 receptor did not differ in
the nociceptive behavioral responses to phase 1 of the formalin test but displayed a
significant reduction of pain behavior during phase 2 (Zeitz et al., 2002). Furthermore,
activity of spinal dorsal horn neurons during the formalin test was significantly attenuated
during phase 2 in knock-out mice compared to wild-type (Zeitz et al., 2002). These
28
findings implicate a facilitatory role of 5-HT in spinal pain transmission, especially under
persistent pain conditions.
2.4 Urinary Bladder: Physiology and Interaction with Stress and Serotonin
2.4.1%%Bladder%Innervation%
The bladder is innervated by 3 major nerves: the hypogastric, pelvic, and
pudendal, which extend from the thoracolumbar and lumbosacral spinal cord segments
(De Groat, 1986, 1998). Afferent innervation of the bladder is primarily through the
hypogastric and pelvic nerves with cell bodies located in thoracolumbar and lumbosacral
dorsal root ganglia, respectively. Information related to bladder filling is generally
transmitted via the hypogastric and pelvic nerve, whereas messages encoding a full
bladder are transmitted via the pelvic and pudendal nerve (Andersson, 2002). Bladder
afferents terminate in laminae I, V, and VII in the spinal cord dorsal horn, where they
form synapses with second-order neurons (Morgan, Nadelhaft, & de Groat, 1981; Thor,
Morgan, Nadelhaft, Houston, & De Groat, 1989). Sensory information from the bladder
travels through Aδ-fibers and C-fibers (Habler, Janig, & Koltzenburg, 1990, 1993).
Both, to some degree, transmit information regarding bladder filling, but under conditions
of noxious stimulation, such as over-filling, injury, or inflammation, C-fibers represent
the majority of transmission fibers (de Groat, 1998).
Control of micturition is influenced by spinal and bulbospinal reflexes.
Sympathetic spinal reflexes inhibit bladder contractions and increase urethral muscle tone
during bladder filling. When the bladder reaches its urine capacity, a parasympathetic
spinobulbospinal reflex activating the pontine micturition center causes the bladder to
29
contract and relaxes urethral muscle, allowing voiding of urine to take place (de Groat,
1998).
2.4.2 Models of Bladder Nociception
In humans with IC, symptoms and pathologies are not consistent across the board.
For example, cystoscopy of IC patients may reveal submucosal petechial hemorrhages
(glomerulations), Hunner’s fissures (ulcers), or a combination of both. However, only a
small percentage of patients have Hunner’s ulcers, and these patients tend to experience
greater severity of symptoms (Tomaszewski et al., 2001; Warren, Jackson, Langenberg,
Meyers, & Xu, 2004). Recent data from women undergoing tubal ligation revealed that
glomerulations may also be present in bladders of women without IC (Hanno, Burks, et
al., 2011; Payne, Joyce, Wise, & Clemens, 2007). Examination of biopsy tissue may or
may not reveal inflammation, and bladders may appear completely normal (Waxman,
Sulak, & Kuehl, 1998b). Bearing this in mind, it is difficult to produce an animal model
that truly mimics the general population of IC patients.
The most common animal models of bladder pain typically involve administration
of an agent into the bladders of rats, rabbits, and monkeys to induce an inflammatory
response (Ghoniem, Shaaban, & Clarke, 1995; Kato, Kitada, Longhurst, Wein, & Levin,
1990; Shimizu, Kawashima, & Hosoki, 1999). These irritants include acetic acid,
acetone, croton oil, lipopolysaccharide, mustard oil, ovalbumin, turpentine, and zymosan
(Ghoniem et al., 1995; Kato et al., 1990; McMahon & Abel, 1987; Randich, Uzzell,
Cannon, & Ness, 2006; Shimizu et al., 1999; Westropp & Buffington, 2002). Changes
observed in these models include an increased presence of inflammatory cells such as
30
mast cells and neutrophils, decreased bladder capacity, decreased voiding volume,
bladder hyperreflexia, and plasma extravasation (Elgebaly et al., 1992; McMahon &
Abel, 1987; McMahon, Dmitrieva, & Koltzenburg, 1995). These models produce
urodynamic effects, similar to what is observed in IC patients, such as decreased bladder
capacity and decreased voiding volume (Kuo, Chang, & Hsu, 1992). Biopsies of bladder
tissue frequently reveal submucosal inflammation with infiltrates (Rosamilia, Igawa, &
Higashi, 2003).
Evaluating bladder nociception is most commonly and reliably performed by
measuring the VMR response to bladder distension (Ness, Lewis-Sides, & Castroman,
2001; Su, Riedel, Leon, & Laping, 2008b). The bladder is distended in a graded manner
(10-60 mmHg) by air administration via a transurethral catheter, and electrodes are
placed in the external oblique musculature of the rat to record abdominal contractions to
distensions. UBD produces increases in abdominal EMG activity, heart rate, and arterial
blood pressure in female rats (Ness et al., 2001). Intravesical instillation of the yeast cell
wall component, zymosan, produces an augmentation of these responses to UBD
(Randich et al., 2006). Bladder histology in rats with zymosan-induced inflammation
was similar to studies in humans with IC demonstrating essentially normal bladder
histology in that there were no gross changes to bladder thickness, fibrosis, or mast cells
(DeBerry, Randich, Shaffer, Robbins, & Ness, 2010). Furthermore, rats with bladders
inflamed with zymosan showed an increased VMR response to intravesical ice-water
testing-- a parallel finding to a human study in which IC patients reported increased pain
to intravesical ice-water compared to healthy controls (Mukerji et al., 2006; Randich,
Mebane, & Ness, 2009).
31
A critical finding among human IC patients is the correlation of stress and anxiety
with exacerbation of symptoms. Rothrock et al. (2001) reported greater levels of daily
stress and bladder symptoms in IC patients vs. matched controls who were asked to keep
a one-month diary of symptoms and stress levels. A positive correlation was also
observed between disease severity and symptoms of disease/stress levels in IC patients.
Patients with IC had higher urinary cortisol levels compared to controls (Lutgendorf et
al., 2002). Stress-induced bladder hypersensitivity can be produced in animals using a
chronic footshock paradigm. Seven consecutive days of chronic intermittent footshock
produces a reliable increase in the magnitude of the EMG response to UBD (Robbins &
Ness, 2008). This stress-induced hypersensitivity model may be of greater clinical
relevance due to the comorbidity of anxiety-related disorders in IC patients (Chung et al.,
2014) and the difficulty of diagnosis based on histological observations (Waxman, Sulak,
& Kuehl, 1998a).
2.4.3 Role of Serotonin in Bladder Function
Serotonin influence on bladder activity is not straightforward; most reports
conclude that the site of action of serotonergic modulation takes place within the CNS.
Intravenous and intrathecal serotonergic agonists generally facilitate sympathetic activity
and suppress parasympathetic activity (Espey, Downie, & Fine, 1992; Thor, Hisamitsu, &
de Groat, 1990; Thor, Katofiasc, Danuser, Springer, & Schaus, 2002). The raphe nuclei
send serotonergic projections to the lumbosacral spinal cord, where multiple 5-HT
receptor subtypes have been localized, including 5-HT1A, 5-HT1B, 5-HT1D, 5-HT2A,
and 5-HT3 receptors. 5-HT1A and 5-HT3 receptors are predominantly expressed and are
32
the focus of 5-HT receptor studies of bladder function in the literature Specifically, 5HT1A receptors are believed to have an excitatory influence on micturition at supraspinal
and spinal levels (Ramage, 2006). 5-HT1A receptor activation by intrathecal agonists
increased bladder contractions (Kakizaki, Yoshiyama, Koyanagi, & De Groat, 2001) and
decreased micturition pressure and urine volume voiding threshold in rats (Conley,
Williams, Ford, & Ramage, 2001). The 5-HT1A receptor antagonist, WAY 100635,
given intravenously increased bladder capacity in anesthetized and unanesthetized rats in
a dose-dependent manner (Conley et al., 2001; Testa et al., 1999). Mediation of bladder
function via 5-HT3 receptors is not as well characterized and differs between studies in
cats and rats. In the cat, intrathecal blockade by the 5-HT3 receptor antagonist,
zatosetron, resulted in decreased volume threshold for micturition (Espey & Downie,
1995). Antagonists also produced an augmentation in pelvic nerve-evoked activity in the
thoracolumbar spinal cord (Espey, Du, & Downie, 1998). In rats, neither intravenous or
intracerebroventricular administration of agonists nor antagonists to 5-HT3 receptors
produced any change to bladder contractility or capacity (Ishizuka et al., 2002; Testa et
al., 2001).
2.5 Spinal Neuronal Characterization
Neurons of the spinal cord dorsal horn that respond to mechanical stimulation of
the bladder have been systematically characterized and can be divided into two distinct
populations, Type I and Type II (Ness & Castroman, 2001). This nomenclature is
analogous to that used in models of colorectal distension, which label neurons as Abrupt
and Sustained, respectively (Ji, Murphy, & Traub, 2003; Ness & Gebhart, 1989). While
33
both neuronal populations respond in a graded manner to increasing intravesical pressure
(Ness & Castroman, 2001), there are differences between Type I and Type II neurons.
The first distinction is in the response to counter-irritation, also referred to as a
heterotopic noxious conditioning stimulus (HNCS), such as a painful pinch or noxious
heat applied to a dermatome distal to the recording site. Type I neuronal activity is
inhibited by HNCS, while Type II neuronal activity is not inhibited by similar stimuli
(Ness & Castroman, 2001).
Another way these two neuronal populations differ is in their response to
analgesics. Intravenous morphine and lidocaine produced a dose-dependent inhibition of
UBD-evoked activity in Type II neurons, but no effect of these drugs was found in Type I
neurons (Ness & Castroman, 2001). In rats receiving morphine, intravenous naloxone
reversed the inhibitory effects of morphine Type II neurons are thought to send excitatory
pain signals to higher-order brainstem nuclei, while Type I neurons send inhibitory
messages involved in pain perception.
These two neuronal types can be further characterized by their responses to
zymosan-induced bladder inflammation. Spontaneous and UBD-evoked activity of Type
I neurons was either decreased or unaffected following inflammation, while Type II
neurons showed increased spontaneous and evoked activity (Ness, Castroman, &
Randich, 2009).
In addition to Type I and Type II classification, neurons that respond to bladder
distension can also be categorized based on cutaneous receptive field properties. Class 2
or WDR neurons respond to noxious and non-noxious cutaneous stimuli, while Class 3 or
NS neurons respond only to noxious stimuli. Class 1 neurons respond to non-noxious
34
stimulation only. One electrophysiological study reported that of the Type I neurons,
88% were found to be Class 2 and 12% were Class 3. Of the Type II neurons, 60% were
Class 2 and 40% were Class 3 (Ness & Castroman, 2001).
35
CHAPTER 3
METHODS
3.1 Selection of Species
Female virgin rats were used in all experiments. Rats were chosen based on their
extensive use in behavioral, neurochemical, neurophysiological, and pharmacological
studies of visceral pain, as well as their similarities shared with primates (Willis, 1985).
Females were chosen because of the disproportionate bias toward women in the patient
population of IC with the end result of this research to be instrumental in the translation
from bench to bedside (Hanno, Burks, et al., 2011).
Sprague Dawley rats weighing 200-250 g were used in methodological
development experiments. Lewis rats weighing 150-200 g were used in all other
experiments, including methodological development. All rats were obtained from Harlan
(Prattville, AL, USA). Rats were allowed ad libitum access to food and water in
temperature-controlled quarters. The light-dark cycle for all rats was 06:00-18:00. A
one-week habituation period was allowed from the date of delivery to our animal facility
to the commencement of any experimental procedures. All studies were approved by the
University of Alabama at Birmingham Institutional Animal Care and Use Committee and
conformed to the guidelines of the International Association for the Study of Pain.
36
3.2 Anesthesia
Rats were anesthetized throughout all surgical and pretreatment procedures. Rats
received an inhalation induction of anesthesia using a tight-fitting mask, which delivered
an isoflurane/oxygen mixture with levels of isoflurane at 5%. All surgical procedures
(venous and tracheal cannulae, intravesical catheters, incisions, and injections) occurred
under 3% isoflurane anesthesia. In spinal electrophysiological experiments, intratracheal,
intravenous, and intravesical cannulae were placed, at which point the animal was moved
to an artificial ventilator maintained at 62 bpm and placed on a heating pad to maintain
body temperature at ~37C. After electrode placement, anesthesia was reduced to 0.750.8% isoflurane for the duration of neuronal recording. In the VMR experiments
anesthesia was maintained at 1-1.25% isoflurane. This level of anesthesia is sufficient to
prevent spontaneous movement, but still allows for flexion-withdrawal reflexes in
response to noxious stimuli.
3.3 Footshock Protocol
Two groups of rats were established. The experimental group was termed chronic
footshock and the control group was termed non-footshock. Rats in both groups were
placed inside of operant conditioning boxes contained within sound and light attenuating
chambers. In the chronic footshock group, shocks of 1.0 mA intensity (1 sec duration)
were delivered via a parallel rod floor 30 times over a 15 min period on a variable
interval schedule which consisted of randomized inter-shock intervals ranging from 1 sec
to 3 min. Footshock treatments occurred once per day for 7 days. Rats in the non-
37
footshock group were placed in the chambers for 15 min once per day for 7 days, but did
not receive footshock.
3.4 Urinary Bladder Distension
A 22-gauge polytetrafluoroethylene angiocather was transurethrally placed in the
bladder and held by a tight suture around the distal urethral orifice. Intravesical pressure
was monitored continuously by an inline, pneumatically-linked, low-volume pressure
transducer and was controlled using a pressure control device (Anderson 1987). Bladders
were distended in a phasic manner with constant-pressure air for 20 sec durations via the
urethral catheter. In the VMR experiments, baseline responses to three 60 mmHg
distensions were followed by ascending graded distensions (10-60 mmHg). In
electrophysiology experiments, baseline neuronal responses (consisting of at least 3
trials) were recorded using phasic distending pressures of 60 mmHg, followed by
responses to ascending graded distensions at pressures of 20, 40, and 60 mmHg. The
intertrial interval was 3 min.
3.5 Receptor Antagonists
Receptor antagonists, WAY 100635 and ondansetron, were obtained from Sigma
(St. Louis, MO, USA). All drugs were dissolved in 15 µl physiological saline (0.9%
NaCl in ultrapure water [Millipore,$Billerica, MA, USA]), and the saline vehicle was
used in control experiments. In VMR experiments, 10 µg of receptor antagonists were
administered. In electrophysiology experiments, ondansetron was administered at a dose
of 100 µg. Compounds were chosen based on their selectivity for 5-HT receptors. WAY
38
100635 selectively blocks the 5HT1A receptor, and ondansetron selectively blocks the
5HT3 receptor. Drug doses were chosen based on a previous study in which 10 µg of
either WAY 100635 or ondansetron significantly inhibited VMR responses to UBD in
rats with zymosan-induced bladder inflammation (Randich, Shaffer, et al., 2008).
3.6 Implantation of Intrathecal Catheters
Under deep anesthesia (isoflurane 3%), rats were secured in a stereotaxic device.
Catheters consisted of polyethylene (PE) 10 tubing (BD Intramedic, NJ, USA). A loose
knot was formed in the tubing and secured using dental cement. The catheters were
trimmed 7.8 cm below the knot. Using a #11 scalpel blade, a 1 cm midline incision was
made to expose the atlanto-occipital membrane. A small slit was made in the atlantoocciptial membrane and the catheter inserted and threaded caudally to the L6-S1 spinal
cord region. Sutures were placed around the knot in the catheter in the muscle covering
the atlanto-occipital membrane to prevent catheter migration. At the end of the testing
procedure, drug administration at the target location in the spinal cord was verified in a
subset of rats with Evan’s blue injection through the intrathecal catheter.
3.7 Assessment of VMR
The VMR is defined as a reflex contraction of abdominal muscles in response to
visceral stimulation, particularly noxious stimulation. This reflex indicates a noxious
response, and this model of visceral pain measurement has been characterized and
reproduced by many investigators in models of bladder and colorectal pain (Castroman &
39
Ness, 2001; Ness & Gebhart, 1988; Ness et al., 2001; Su, Riedel, Leon, & Laping,
2008a).
Following footshock or non-footshock on the seventh day, animals were
immediately anesthetized with isoflurane and a transurethral catheter placed for bladder
distension (section 3.4). Platinum or silver wire electrodes (two recording and one
ground electrode) were inserted into the left external oblique muscle through an incision
in the abdominal skin for differential amplification of EMG activity. Anesthesia was
lowered to between 1-1.25 % isoflurane, after which time the animal was tested for a
hind paw withdrawal reflex. If no reflex was observed, the animal was allowed more
time to acclimate to the anesthesia level before initiation of testing. The 5-HT receptor
antagonists, ondanestron or WAY 100635, or saline vehicle was administered via
intrathecal catheter. Responses to UBD were recorded 10 min following ondansetron and
15 min following WAY 100635 or saline administration. The bladder was distended via
air pressure according to the following sequence: 3- 20 sec 60 mmHg distensions in
order to overcome initial sensitivity and establish stable EMG responses. Immediately
following baseline recordings, responses to graded distensions were obtained. The intertrial interval was 3 min.
Abdominal EMG activity was amplified using a Grass P511 amplifier (Grass
Technologies, Warwick, RI, USA) and captured and recorded using a CED 1401
interface and Spike 2 software. The amplifier settings were as follows: EMG
amplification factor=200; low frequency filter=10Hz; high frequency filter=3kHz;
sample rate=10kHz. The VMR response was defined as: (rectified EMG activity during
UBD - rectified baseline EMG prior to UBD) / (rectified baseline EMG).
40
3.8 Enzyme-Linked Immunosorbant Assay (ELISA)
3.8.1 Tissue Collection
Two groups of rats, chronic footshock and non-footshock, were used to measure
5-HT, 5-HIAA, and corticosterone. After cessation of the footshock protocol, rats were
immediately anesthetized using 5% isofluorane. All tissues were collected between
08:00 and 10:00 over the course of four days. A midline incision was made to expose
the atlanto-occipital membrane. CSF was collected via needle aspiration by puncturing
the atlanto-occipital membrane with a 30 g needle and transferred to a 0.5 µl centrifuge
tube. The aspirate was frozen on dry ice. Blood was collected by cardiac puncture using
a 20 g needle. Serum was obtained by allowing the blood to clot at room temperature
(RT) for 90 min and then centrifuging for 15 min at 2000 x g. The supernatant was
transferred to 1.5 µl centrifuge tubes and frozen at -80°C. Animals were then decapitated
and the spinal cord removed by hydraulic extrusion. Lumbosacral segments (5 mm) were
isolated and dissected, placed into 1.5 µl centrifuge tubes, and frozen on dry ice. Spinal
cord tissue was homogenized in 0.01 M phosphate buffered saline with 1% protease
inhibitor cocktail (Thermo Scientific, Rockford, IL, USA). The homogenates were
centrifuged for 15 min at 16000 x g at 4°C. The supernatant was removed and total
protein measured using the Pierce BCA Protein Assay Reagent Kit (Rockford, IL, USA).
All samples remained frozen at -80°C until processing for ELISA.
41
3.8.2 Serotonin
The Serotonin (Research) ELISA (ALPCO Diagnostics, Salem, NH, USA) was
performed using 48 µg of protein per sample for spinal cord tissue and 2 µl of CSF per
sample. Samples, standards, and controls were acylated for 30 min at RT. The acylated
samples, standards, and controls were then transferred in duplicate to a microtiter plate
and incubated with rabbit 5-HT antiserum for 24 h at 4°C. The plate was washed and
anti-rabbit IgG conjugated with peroxidase was added and allowed to incubate for 30 min
at RT. The plate was washed again and the substrate, tetramethylbenzidine (TMB), was
added. The plate was incubated in the dark for 25 min at RT. Stop solution (0.25 M
sulphuric acid) was added to each well and the optical density was read at 450 nm using a
Fluostar Omega plate reader (BMG Labtech, Offenburg, Germany). The concentrations
of samples were multiplied by a correction factor of 50.
3.8.3 5-Hydroxyindoleacetic Acid (5-HIAA)
The 5-HIAA ELISA (ALPCO Diagnostics, Salem, NH, USA) was performed
using 96 µg of protein for spinal cord samples and 5 µl of CSF per sample. Standards,
samples, and controls were diluted, methylated for 20 min at RT, and diluted further.
The methylated standards, samples, and controls were pipetted in duplicate onto a
microtiter plate. Rabbit anti-5-HIAA was added to each well and the plate was incubated
for 1 h at RT. The plate was washed and peroxidase-conjugated anti-rabbit IgG was
added, and the plate was again incubated for 1 h at RT. The plate was washed again and
the substrate, TMB, was added. After a 25 min incubation in the dark at RT, 0.25 M
sulphuric acid was added to stop the reaction. The optical density was read at 450 nm
42
using a Fluostar Omega plate reader (BMG Labtech, Offenburg, Germany).
3.8.4 Corticosterone
Serum obtained from chronic footshock and non-footshock rats was analyzed for
corticosterone content (EIA kit from Cayman Chemical Company, Ann Arbor, MI,
USA). 10 µl of serum was added to 200 µl of diluent, and then 50 µl of the diluted
sample from each animal and corticosterone standards were added to a rabbit anti-sheep
IgG coated microtiter plate in duplicate. Corticosterone conjugated to acetylcholine
esterase and sheep anti-corticosterone were added to the plate and allowed to incubate for
2 h at RT. The plate was washed and Ellman’s reagent was added. The plate was
covered and incubated in the dark for 75 min at RT at which point the optical density was
read at 412 nm using a Fluostar Omega plate reader (BMG Labtech, Offenburg,
Germany).
3.9 Spinal Electrophysiology
3.9.1 Surgical Preparation
The external jugular vein was cannulated using PE10 tubing. Tracheal and
transurethral cannulae were placed for artificial respiration and UBD, respectively. A
laminectomy was performed to expose the L6-S2 spinal cord region. Rats were
suspended by vertebral clamps placed rostral and caudal to the laminectomy for
stabilization. The dura mater was cut and removed to expose the spinal cord.
Physiological saline-saturated gauze was applied to the spinal cord to prevent damage
43
due to drying. Tungsten microelectrodes (Microprobes, Gaithersburg, MD, USA) were
placed into the dorsal spinal cord 0-1.0 mm lateral to midline and 0.1-1.2 mm deep for
single-unit extracellular recordings and rats were paralyzed using pancuronium bromide
(0.2 mg/h, intravenous) to prevent electrode movement. UBD was used as the search
stimulus, and neurons that were consistently excited by UBD were isolated for use for the
remainder of the experiment.
3.9.2 Quantification Of Neuronal Responses
Neuronal responses to UBD were monitored on an oscilloscope and quantified by
discrimination from background and converted to uniform pulses. The responses were
saved on a computer as peristimulus-time histograms. Spontaneous activity was
determined as the average rate of action potentials in the 10 sec period prior to onset of
UBD. Total activity was determined as the rate of action potentials in the 20 sec period
during the UBD stimulus. Evoked activity was calculated as the difference between the
total activity and spontaneous activity.
3.9.3 Neuronal Characterization
Neurons responding to UBD were characterized based on their responses to UBD
and somatic mechanical stimuli and their receptive fields were mapped. Initially neurons
were characterized based on their responses to noxious cutaneous (heterotopic noxious
conditioning stimuli; HNCS) input to upper thoracic and cervical dermatomes.
Spontaneous activity was recorded 10 sec before and 10 sec after applying a pinch using
an alligator clip to apply a constant and consistent noxious pressure to the skin overlying
44
the scapulae. Neurons were classified as Type I if their response to UBD was inhibited
>20% by HNCS or Type II if their response was excited, unaffected, or inhibited <20%
by HNCS. Only Type II neurons were tested further. Type II neurons responding to
weak tactile stimuli, such as brushing of the skin with a cotton-tipped applicator, as well
as intense mechanical stimuli, such as pinching of the skin or hindpaw with an alligator
clip, were classified as WDR. Those responding only to intense mechanical stimulation
were classified as NS. Responses to UBD as described above were then recorded for
individual neurons. All responses were recorded and saved on a computer for
quantification and analysis.
After determining baseline responses to visceral and somatic stimuli, 10 µl of the
receptor antagonist or saline vehicle was delivered directly on top of the exposed spinal
cord. After 15 min, responses to UBD and cutaneous stimuli were again recorded for
individual neurons as described above. Upon termination of neuronal recording, rats
were euthanized by overdose of inhaled anesthetic (isoflurane) and cardiac puncture.
3.10 Statistical Analyses
3.10.1 Statistical Significance
All comparisons were considered significantly different at p≤0.05. All post-hoc
tests were performed using Holm’s correction to maintain a family-wise α=0.05 (Holm,
1979).
45
3.10.2 Visceromotor Reflex Response
Evoked abdominal EMG responses were analyzed using a repeated-measures
analysis of variance (ANOVA), comparing stress (chronic footshock vs. no footshock),
drug (saline, ondansetron, or WAY 100635), and distending pressures (10-60 mmHg).
Separate ANOVAs were performed to answer separate questions. The first ANOVA
assessed the effect of stress on EMG activity in the presence of the selective antagonist
(chronic footshock vs. no footshock, all antagonists). The second ANOVA assessed
EMG activity after the selective antagonist only in chronic footshock-treated animals
(antagonist vs. saline, all chronic footshock). The third ANOVA assessed EMG activity
after the selective antagonist only in non-footshock treated animals (antagonist vs. saline,
all no footshock).
3.10.3 Enzyme-Linked Immunosorbant Assay
Two-tailed, independent samples t-tests were used to compare the values of spinal
cord corticosterone, 5-HT, 5-HIAA, and 5-HIAA/5-HT levels, separately, between rats
exposed to chronic footshock stress vs. sham-stress.
3.10.4 Spinal Electrophysiology
3.10.4.1 Graded UBD. Lumbosacral dorsal horn neuronal activity in response to
UBD was analyzed using a repeated-measures ANOVA comparing stress (chronic
footshock vs. no footshock), drug (saline or ondansetron), and distending pressures (20,
40, and 60 mmHg). Separate ANOVAs were performed to answer separate questions.
The first ANOVA assessed the effect of stress on neuronal responses in the presence of
46
the selective antagonist (chronic footshock vs. no footshock, all antagonists). The second
ANOVA assessed neuronal activity after the selective antagonist only in chronic
footshock-treated animals (ondansetron vs. saline, all chronic footshock). The third
ANOVA assessed neuronal activity after the selective antagonist in only non-footshock
treated animals (ondansetron vs. saline, all no footshock).
3.10.4.2 Baseline UBD. Three baseline measures of UBD-evoked dorsal horn
neuronal activity were averaged and compared using an independent samples t-test.
Comparisons were made of chronic footshock vs. no footshock in saline or ondansetron
treated rats separately. Comparisons were also made of saline vs. ondansetron in
footshock or non-footshock treated rats separately.
3.10.4.3 Neuronal distribution. The effect of stress (chronic footshock vs. nonfootshock) on the ratio of WDR to NS neurons was assessed separately for Type II
neurons using Fisher’s Exact Test.
47
CHAPTER 4
METHODOLOGICAL DEVELOPMENT
4.1 Strain Selection
Sprague Dawley rats are one of the most widely used strains in scientific and
medical research. They are an outbred strain derived from the Wistar rat. One notable
characteristic is their ease of handling. Phenotypically, they appear more docile and
resilient to stress and anxiety. Originally, Sprague Dawley rats were chosen for the
experiments contained within this thesis. Sprague Dawley rats had been used in all of the
preliminary supporting studies utilizing the footshock-induced urinary bladder
hypersensitivity model (Marek et al., 1992; Robbins & Ness, 2008). However, since
stress-induced hypersensitivity carries a substantial degree of variability, it seemed
worthwhile to determine if another strain may be more suitable to this line of research.
Lewis rats were chosen as a candidate because they have been documented to
exhibit a higher degree of anxiety (Ramos, Berton, Mormede, & Chaouloff, 1997).
Lewis rats display high levels of avoidance on the elevated plus maze and in the central
area of the open field test. Diazepam administration significantly increased the amount
of time spent in the open arm of the elevated plus maze, demonstrating that the anxiety
behaviors observed can be pharmacologically manipulated (Ramos et al., 1997). Lewis
rats are often used in research relating to deficits in immune function, such as
experimental allergic encephalitis and rheumatoid arthritis. This is due to the fact that an
48
inadequate HPA response to stress can lead to an increased allostatic load (McEwen &
Stellar, 1993). Indeed, the Lewis rat displays a hypoactive HPA axis (Sternberg et al.,
1989). The disregulation of HPA activity leads to increases in pro-inflammatory
cytokines (McEwen, 1998). The Lewis rat appeared to be a sound choice due to its
susceptibility to stress and pain-related disorders. Prior to our studies, the Lewis rat had
never been tested as a model of stress-induced bladder hypersensitivity.
The VMR responses to UBD in Sprague Dawley and Lewis rats were measured
and compared in response to chronic footshock stress. For each strain two groups were
established, chronic footshock and non-footshock. Sample sizes are as follows: Sprague
Dawley-chronic footshock (n=5), Sprague Dawley-non-footshock (n=5), Lewis-chronic
footshock (n=6), Lewis-non-footshock (n=6). The footshock protocol was carried out as
described in section 3.3. Following footshock, the abdominal EMG responses to UBD
were recorded in each rat in ascending pressures from 10-60 mmHg as previously
described in section 3.7. The rats did not have intrathecal catheters placed, and no drugs
or vehicle were administered during any time of pretreatment or testing.
A main effect of stress was observed in abdominal EMG responses to UBD
following chronic footshock or no footshock in the Lewis strain of rats but not in the
Sprague Dawley strain (Lewis: F(1,10)=9.413 p<0.05; SD: F(1,8)=0.014, p=0.907).
Post-hoc analyses revealed significantly greater responses following chronic footshock at
UBD pressures of 30-60 mmHg in Lewis rats (p<0.05). In a separate analysis examining
the effect of strain, there was no difference in abdominal EMG responses to UBD when
comparing the strain of rat in only chronic footshock treated rats (F(1,9)=0.082,
p=0.781). However, among non-footshock animals, there was a main effect of strain
49
such that VMR responses were significantly lower in Lewis rats compared to Sprague
Dawley (F(1,10)=9.75, p<0.05). Post-hoc analyses showed significant differences at
UBD pressures of 50-60 mmHg (p<0.05). These results are presented in Figure 4.1.
In a subset of Lewis rats, serum corticosterone was measured (section 3.8.4) in
rats undergoing chronic footshock or no footshock (section 3.3) to determine the validity
of induction of the HPA axis by chronic footshock in Lewis rats. Sample sizes were as
follows: chronic footshock (n=11) and non-footshock (n=14). Figure 4.2 illustrates that
corticosterone was significantly elevated in rats that underwent chronic footshock versus
non-footshock (t(23)=7.78, p<0.001)
These results indicate that the Lewis strain is a more robust and reliable model of
footshock stress-induced bladder hypersensitivity. The Lewis rats have a lower baseline
(i.e. non-stress condition) EMG response to graded UBD than do the Sprague Dawley
rats. This lower baseline activity makes any deviations in the direction of increased
sensitivity to noxious stimulation more easily detectable. Stress-induced alterations can
be achieved in Sprague Dawley rats, as many reports indicate, including those of our own
laboratory (Black, Ness, & Robbins, 2009; Martenson, Cetas, & Heinricher, 2009;
Robbins & Ness, 2008). However, the footshock-induced bladder hypersensitivity in
Sprague Dawley rats is often associated with a higher degree of variability. The
phenomenon may or may not be observed, and when it is, a larger group of animals is
usually required.
Clearly, footshock stress induced a marked increase in corticosterone release in
Lewis rats, indicating a strong HPA-axis stress response. While an increase was also
seen previously in Sprague Dawley rats, Lewis rats had an increase of almost three-fold,
50
while the increase in Sprague Dawley rats was closer to two-fold (Marek et al., 1992).
These results, coupled with the aforementioned stress-induced change in VMR response,
show that the Lewis strain is the superior choice for the experiments contained within this
thesis, as well as for future experiments utilizing the footshock stress-induced bladder
pain model.
4.2 Effect of Intrathecal Catheter
Intrathecal drug delivery is a widely accepted method of administering drugs into
the subarachnoid space clinically in humans and also in animal models in scientific
research. However, in the context of research, placement of the catheter itself should be
viewed as an independent variable. Insertion of the catheter causes changes in intraspinal
pressure and presumably an enhanced inflammatory response to the foreign material. A
search of the literature was unable to cast light on the effect of intrathecal catheter
placement on responses to noxious stimulation and specifically, visceromotor responses.
The following study addresses the role of intrathecal catheter introduction on the VMR
response to UBD in animals with stress-induced urinary bladder hypersensitivy.
One group of rats had an intrathecal catheter placed into the subarachnoid space at
the lumbosacral region (section 3.6) while another group of rats was left intact. Both
groups were subdivided into chronic footshock and non-footshock groups and received
treatments per the footshock protocol (section 3.3). VMR responses to UBD were
recorded (section 3.7). All catheters contained physiological saline. Sample sizes were
as follows: chronic footshock-no catheter (n=6), no footshock-no catheter (n=6), chronic
footshock-catheter (n=9), and no footshock-catheter (n=8).
51
The findings in Table 4.1 indicate a significant main effect of intrathecal catheter
and stress and significant interactions of UBD x catheter, UBD x stress, and UBD x
catheter x stress. Rats in the chronic footshock group without intrathecal catheters had
significantly greater abdominal EMG responses to UBD compared to rats with footshock
and catheters, no footshock and catheters, and no footshock and no catheters. Post-hoc
analyses revealed a significant effect of stress in rats with catheters and no catheters and a
significant effect of catheter in stressed rats at UBD pressures of 50-60 mmHg (p<0.05).
These results are illustrated in Figure 4.3.
These findings suggest that the simple placement of an intrathecal catheter may be
a confounding variable since it produces a significant decrease in the magnitude of the
EMG response to UBD. Although a significant reduction in the EMG response is only
seen in chronically stressed rats when testing for pharmacological manipulations, this
finding may mask the effect of a drug. Specifically, if the expected outcome of drug
administration is to mitigate the stress-induced increase in VMR response, it may prove
more challenging to obtain a significant effect since both the drug and the administration
of vehicle would produce a similar diminishing effect. The effect of the catheter alone
must be taken into account when interpreting data from animals with intrathecallyimplanted catheters. It would prove useful to further examine if there are histological and
biochemical changes that occur due to catheter implantation.
In the experiments described in Specific Aim 1, the choice was made to use
intrathecal catheters because it is the most efficient way to deliver a drug into the
subarachnoid space of a rat. Furthermore, the method has been used for decades in
52
pharmacological animal research (Gustafsson, Post, Edvardsen, & Ramsay, 1985;
Svensson, Persson, Fitzsimmons, & Yaksh, 2013; Yaksh & Rudy, 1976).
4.3 Effect of Serotonin on Chronic Footshock-Induced Bladder Pain
Prior to undertaking the current experiments involving specific serotonergic
receptor antagonists, it needed to be determined if serotonin in general had an influence
in stress-induced bladder hypersensitivity. To achieve this, effects of the non-specific
serotonergic receptor antagonist, methysergide (Sigma, St. Louis, MO, USA), on UBDevoked VMRs was examined. Inthrathecal administration was chosen to determine if the
receptor effects were acting at the spinal cord level.
Two groups of rats were established, chronic footshock and non-footshock. The
footshock protocol was carried out as previously described. On the day of testing, rats
were implanted with intrathecal catheters (section 3.6) and prepped for VMR recording
(Section 3.7). Half of the rats received intrathecal methysergide (30 µg in 15 µl saline)
and half received saline vehicle (15 µl) 15 min prior to UBD testing. EMG responses to
UBD at pressures from 10-60 mmHg were recorded. Sample sizes were as follows:
chronic footshock-methysergide (n=9), chronic footshock-saline (n=7), non-footshockmethysergide (n=7), non-footshock-saline (n=7).
Figure 4.4 shows that abdominal EMG responses to UBD in chronic footshockstressed rats were significantly diminished following intrathecal administration of
methysergide compared to saline vehicle (significant main effect of drug: F(1,14)=6.409,
p<0.05). Post-hoc tests showed significant group differences at UBD pressures of 30-60
53
mmHg (p<0.05). There was no effect of the drug in non-footshock rats (F(1,11)=0.053,
p=0.822).
Spinal administration of the non-specific 5-HT receptor antagonist, methysergide,
significantly attenuated VMR responses to UBD in stressed rats, implicating a facilitatory
role of 5-HT in stress-induced bladder hypersensitivity. This is similar to a previous
report by Randich et al. (2008) in which methysergide significantly reduced VMR
responses in a model of inflammation-induced bladder pain. Since methysergide is a
non-specific antagonist, this warrants further investigation with drugs that target specific
5-HT receptors.
54
Figure 4.1. Group mean abdominal EMG activity at UBD pressures of 10-60 mmHg in
Sprague Dawley and Lewis rat strains. Rats were exposed to footshock (closed circles)
or no footshock (open circles) for 15 min daily for 7 days. Sprague Dawley rats (A)
showed no difference in the magnitude of the EMG response between chronic footshock
and no footshock groups, while chronic footshock significantly increased EMG responses
compared to no footshock in Lewis rats (B). * indicates significantly higher EMG
responses in the chronic footshock group (p<0.05). N=5-6/group.
A
Sprague Dawley
6
Footshock
No Footshock
Group Mean EMG
5
4
3
2
1
0
10
20
30
40
50
60
Bladder Pressure (mmHg)
B
Lewis
6
Footshock
No Footshock
Group Mean EMG
5
4
*$
*$
50
60
3
*$
2
*$
1
0
10
20
30
40
Bladder Pressure (mmHg)
55
Figure 4.2. Serum corticosterone concentration in Lewis rats following chronic
footshock or no footshock. Rats were exposed to footshock (black bar) or no footshock
(gray bar) for 15 min daily for 7 days. Footshock significantly increased levels of
corticosterone compared to no footshock (* p<0.001). N=11-14/group.
Corticosterone
140
Corticosterone (ng/ml)
120
*$
100
80
60
40
20
0
CFS
NFS
56
Figure 4.3. Group mean EMG responses to graded UBD at pressures of 10-60 mmHg in
rats with and without intrathecal catheters. Rats were exposed to footshock or no
footshock for 15 min daily for 7 days. * and ** indicate that EMG responses from rats
with chronic footshock with no catheter are significantly higher than responses with no
footshock-no catheter, chronic footshock-catheter, and no footshock-catheter (p<0.05 and
0.001, respectively). # indicates significantly higher EMG responses with chronic
footshock compared to no footshock (p<0.05). N=6-9/group.
4
**$
**$
Footshock- No Catheter
No Footshock- No Catheter
Footshock- Catheter
No Footshock- Catheter
#$
#$
Group Mean EMG
3
*$
2
*$
#$
#$
1
0
10
20
30
40
Bladder Pressure (mmHg)
57
50
60
Figure 4.4. Group mean EMG responses to graded UBD at pressures of 10-60 mmHg in
rats given intrathecal methysergide or saline. Rats were exposed to footshock or no
footshock for 15 min daily for 7 days. Panel A shows decreased EMG magnitude with
intrathecal methysergide with prior chronic footshock (* p<0.05). Panel B indicates no
change in EMG after methysergide with no footshock. N=7-9/group.
Chronic Footshock
A
5
Group Mean EMG
Methysergide
Saline
*$
*$
4
*$
3
*$
2
1
0
10
20
30
40
50
60
Bladder Pressure (mmHg)
B
No Footshock
5
Group Mean EMG
Methysergide
Saline
4
3
2
1
0
10
20
30
40
50
Bladder Pressure (mmHg)
58
60
Table 4.1. Statistical analyses of EMG responses to graded UBD in rats with or without
intrathecal catheter implantation. Rats were exposed to 15 min of daily chronic
footshock stress or no footshock for 7 days.
Repeated Measures ANOVA
Chronic Footshock vs. No Footshock
Catheter vs. No Catheter
Mean EMG
df
F
Catheter
(1,23)
5.997
Stress
(1,23)
15.877
Catheter x Stress
(1,23)
3.707
UBD x Catheter
(5,115)
4.471
UBD x Stress
(5,115)
13.422
UBD x Catheter x Stress
(5,115)
3.527
59
p-value
0.022
0.001
0.067
0.001
<0.001
0.005
CHAPTER 5
RESULTS
5.1 Specific Aim 1
5.1.1 Purpose
The purpose of Specific Aim 1 was to test the effects of blocking specific
serotonin receptors, 5-HT1A and 5-HT3, on the stress-induced enhancement of the VMR
response to UBD. Rats were exposed to the chronic footshock or no footshock
treatments for 7 days. All animals were implanted with intrathecal catheters that
extended to the lumbosacral region of the spinal cord and were given WAY 100635,
ondansetron, or saline vehicle. VMR responses were recorded in the presence of each
drug in both the stress and no stress groups. Sample sizes are as follows: chronic
footshock-saline (n=9), chronic footshock-WAY 100635 (n=9), chronic footshockondansetron (n=9), non-footshock-saline (n=8), non-footshock-WAY 100635 (n=8), nonfootshock-ondansetron (n=8). In all instances where ANOVA was used to compare
differences in mean EMG recordings, tests were conducted to determine normality of
distribution, homogeneity of variance, and sphericity and were concluded to not be in
violation of these assumptions.
60
5.1.2 Effect of Footshock
ANOVA revealed that chronic footshock treatment significantly increased the
abdominal EMG recordings in response to graded UBD compared to no footshock in rats
given intrathecal saline (main effect of stress: F(1,15)=4.897, p<0.05; interaction of UBD
x stress: F(5,75)=3.994, p<0.01). Post-hoc tests revealed significant group differences at
UBD pressures of 20 and 40-60 mmHg (p<0.05). There were no significant effects of
footshock stress in rats with intrathecal WAY 100635 or ondansetron (WAY:
F(1,15)=1.093, p=0.312; ODS: F(1,16)=0.350, p=0.563). These results are presented in
Figure 5.1.
5.1.3 Effect of WAY 100635
In addition to examining the effect of footshock stress in animals with intrathecal
saline or 5-HT receptor antagonist, the same data presented in 5.1.2 was analyzed as an
effect of drug in separate groups of rats that had similar stress treatments. This section
addresses the effect of WAY 100635, while the following section addresses the effect of
ondansetron. Spinal administration of WAY 100635 did not significantly alter the
magnitude of EMG responses to bladder distension in either the chronic footshock or the
non-footshock condition (CFS: F(1,16)=0.405, p=0.534; NFS: F(1,14)=1.681, p=0.216;
Figure 5.2).
5.1.4 Effect of Ondansetron
Ondansetron given intrathecally had no effect on EMG responses of rats
following chronic footshock or no footshock (CFS: F(1,16)=1.404, p=0.253; NFS:
61
F(1,15)=1.301, p=0.272). However, ANOVA revealed a significant interaction of UBD x
Drug x Footshock (F(5,155)=2.677, p<0.05). These findings are presented in Figure 5.3.
5.2 Specific Aim 2
5.2.1 Purpose
The purpose of Specific Aim 2 was to determine whether levels of serotonin
and/or its metabolite, 5-HIAA, in CSF or lumbosacral spinal cord were altered by chronic
footshock stress. Rats underwent chronic footshock or no footshock treatment, and then
spinal cord and CSF samples were tested using ELISA for 5-HT and H-HIAA. These
two concentrations were then used to calculate the ratio of 5-HIAA to 5-HT, which gives
a better understanding of serotonin turnover due to 5-HIAA being the major metabolite of
serotonin.
5.2.2 Enzyme-Linked Immunosorbent Assay
The results from Specific Aim 2 are presented in Table 5.1 and Figures 5.4-5.6.
Concentrations of 5-HT and 5-HIAA are not significantly changed with chronic
footshock stress compared to sham stress in either lumbosacral spinal cord or CSF.
The ratio of 5-HIAA to 5-HT is not significantly different in footshock or non-footshock
treated rats in both spinal cord and CSF samples.
62
5.3 Specific Aim 3
5.3.1 Purpose
The purpose of Specific Aim 3 was to determine the effect of 5-HT3 receptor
blockade on the activity of spinal dorsal horn neurons in response to UBD in rats with
stress-induced bladder hypersensitivity. Recordings were obtained from neurons that
responded by increasing their activity to mechanical bladder stimulation. Furthermore,
these neurons had to exhibit an increase or no change in the rate of firing (i.e., not
inhibited) in response to a counter-stimulus (see section 3.9.3). Neuronal activity was
recorded in response to graded UBD in both chronically stressed and non-stressed rats
and in the presence of spinal ondansetron or saline vehicle. Dorsal horn neurons were
further classified by their receptive field properties. Sample sizes were as follows:
chronic footshock-saline (n=7), chronic footshock-ondansetron (n=8), non-footshocksaline (n=8), non-footshock-ondansetron (n=8). Where ANOVA was used to determine
differences in neuronal responses as an effect of stress or drug, tests were conducted to
determine normality of distribution, homogeneity of variance, and sphericity. These
assumptions were met in all comparisons except that there was a violation of sphericity in
the comparison of saline vs. ondansetron in stressed rats. In this particular comparison,
there were no clear differences in neuronal responses between the drug and vehicle
groups, therefore no correction of sphericity was made since it would not have affected
the outcome of the ANOVA.
63
5.3.2 Effect of Footshock
Prior to recording neuronal responses to graded UBD, a stable baseline response
was established using a 60 mmHg UBD stimulus. No more than a 10% change was
allowed to occur in 3 sequential trials in order to be considered “stable”. No significant
difference was detected in the mean baseline neuronal responses between chronically
stressed or non-stressed rats administered ondansetron or saline (ODS: t(14)=0.151,
p=0.883; SAL: t(13)=1.939, p=0.075). Following spinal administration of ondansetron or
saline, there was no significant main effect of chronic footshock stress on dorsal horn
neuron excitability in response to graded UBD (ODS: F(1,14)=0.334, p=0.572; SAL:
F(1,13)=1.09, p=0.316). These results are depicted in Figure 5.7.
5.3.3 Effect of Ondansetron
Figure 5.8 shows that the administration of ondansetron did not decrease neuronal
activity in response to UBD in chronically stressed rats (F(1,13)=0.636, p=0.439).
Ondansetron also did not change neuronal responses in non-stressed rats (F(1,14)=0.058,
p=0.813). Mean baseline neuronal activity trended toward a significant increase in
ondansetron treated rats compared to saline treated rats in the chronic footshock but not
the non-footshock group (CFS: t(13)=2.008, p=0.066; NFS: t(14)=0.175, p=0.863).
5.3.4 Percent of Baseline Comparisons
In the previous two sections, the effects of footshock and of ondansetron were
analyzed using group mean neuronal discharges to compare neuronal responses.
Furthermore, the analyses utilized a between-subjects design. The neuronal response
64
data from Specific Aim 3 was also analyzed as a percentage of baseline and using a
within-subjects design. Specifically, baseline and graded UBD responses were recorded
before and after spinal drug administration. Graded neuronal responses were normalized
as a percentage of the pre-drug baseline response average. These alternative analyses
were conducted as a means to reduced variability within comparison groups.
5.3.4.1 Effect of Footshock. The pre-drug baseline neuronal responses from
chronic footshock rats and non-footshock rats were compared. An independent samples t
test did not reveal a difference in baseline responses between footshock and nonfootshock groups (t(29)=0.057, p=0.995). A repeated measures ANOVA did not detect
an effect of stress (F(1,29)=0.803, p=0.378).
5.3.4.2 Effect of Drug. Pre- and post-drug responses were compared in rats with
chronic footshock and no footshock. Baseline responses were compared in each
treatment group before and after drug administration. There were no detectable
differences observed in baseline neuronal responses after administration of ondansetron
or saline vehicle in either stressed or non-stressed rats (CFS-ODS: t(14)=0.230, p=0.821;
NFS-ODS: t(9)=0.419, p=0.685; CFS-SAL: t(11)=-0.388, p=0.705; NFS-SAL:
t(13)=1.202, p=0.250). Furthermore, a repeated measures ANOVA was conducted on the
responses to graded bladder distension in each group. No effects of ondansetron or saline
were found in stressed or non-stressed rats (CFS-ODS: F(1,13)=4.160, p=0.62; NFSODS: F(1,14)=0.048, p=0.830; CFS-SAL: F(1,12)=0.639, p=0.440; NFS-SAL:
F(1,14)=2.244, p=0.156).
65
5.3.5 Neuronal Characterization
According to predetermined guidelines, only Type II neurons were chosen for
experiments in Specific Aim 3; that is, the neurons responded to counter-stimulation by
an increase or no change in activity. All but one neuron retained this characteristic after
spinal ondansetron or saline in both the stressed and non-stressed groups. Nearly all of
the neurons from rats in the chronic footshock group were classified as WDR (87.5%)
compared to NS (12.5%), while neurons from rats in the non-footshock group were
mostly NS (62.5%; WDR: 37.5%). A Fisher’s exact test indicated that, indeed, neurons$
from$rats$exposed$to$footshock$were$more$likely$to$be$WDR,$and$those$from$rats$in$
the$nonNstress$group$were$more$likely$to$be$NS$(p<0.05). The depth from the spinal
cord dorsum was recorded for most neurons and is presented in Figure 5.9.
66
Figure 5.1. Group mean EMG responses to graded UBD at pressures of 10-60 mmHg.
Rats were exposed to footshock (closed circles) or no footshock (open circles) for 15 min
daily for 7 days and administered either intrathecal saline, WAY 100635, or ondasetron.
Panel A shows chronic footshock significantly increased EMG responses in rats with
intrathecal saline at pressures 40-60 mmHg (*p<0.05). EMG responses were not
different between chronic footshock and no footshock with intrathecal WAY 100635 (B)
or ondansetron (C). N=8-9/group.
Saline
A
2.0
Footshock
No Footshock
*$
Group Mean EMG
1.5
*$
1.0
*$
0.5
*$
0.0
10
20
30
40
50
60
50
60
50
60
Bladder Pressure (mmHg)
WAY 100635
B
2.0
Footshock
No Footshock
Group Mean EMG
1.5
1.0
0.5
0.0
10
20
30
40
Bladder Pressure (mmHg)
C
Ondansetron
2.0
Footshock
No Footshock
Group Mean EMG
1.5
1.0
0.5
0.0
10
20
30
40
Bladder Pressure (mmHg)
67
Figure 5.2. Group mean EMG responses to graded UBD at pressures of 10-60 mmHg.
In panel A, rats were exposed to footshock for 15 min daily for 7 days and administered
either intrathecal WAY 100635 or saline. Panel B shows responses from rats exposed to
no footshock for 15 min daily for 7 days and administered either intrathecal WAY
100635 or saline. There was no difference in EMG magnitude between saline and WAY
100635 treated rats following chronic footshock or no footshock. N=8-9/group.
Chronic Footshock
A
2.0
WAY 100635
Saline
Group Mean EMG
1.5
1.0
0.5
0.0
10
20
30
40
50
60
50
60
Bladder Pressure (mmHg)
B
No Footshock
2.0
WAY 100635
Saline
Group Mean EMG
1.5
1.0
0.5
0.0
10
20
30
40
Bladder Pressure (mmHg)
68
Figure 5.3. Group mean EMG responses to graded UBD at pressures of 10-60 mmHg.
In Panel A, rats were exposed to footshock for 15 min daily for 7 days and administered
either intrathecal ondansetron or saline. Panel B shows responses from rats exposed to
no footshock for 15 min daily for 7 days and administered either intrathecal ondansetron
or saline. There was no difference in EMG magnitude between saline and ondansetron
treated rats following chronic footshock or no footshock. N=8-9/group.
Chronic Footshock
A
2.0
Ondansetron
Saline
Group Mean EMG
1.5
1.0
0.5
0.0
10
20
30
40
50
60
50
60
Bladder Pressure (mmHg)
No Footshock
B
2.0
Ondansetron
Saline
Group Mean EMG
1.5
1.0
0.5
0.0
10
20
30
40
Bladder Pressure (mmHg)
69
Figure 5.4. Serotonin levels in lumbosacral spinal cord and cerebrospinal fluid. Rats
were exposed to footshock (black bars) or no footshock (gray bars) for 15 min daily for 7
days. Panel A shows serotonin levels in lumbosacral spinal cord. Panel B shows
serotonin levels in CSF. There were no differences in serotonin levels between rats with
chronic footshock and no footshock in either tissue. N=13-15/group.
A
5-HT Spinal Cord
200
5-HT (ng/ml)
150
100
50
0
CFS
B
Col 1 vs Col 2 - Col 14
Col 1 vs Col 15 - Col 29
NFS
5-HT CSF
200
5-HT (ng/ml)
150
100
50
0
CFS
NFS
70
Figure 5.5. 5-HIAA levels in lumbosacral spinal cord and cerebrospinal fluid. Rats
were exposed to footshock (black bars) or no footshock (gray bars) for 15 min daily for 7
days. Panel A shows 5-HIAA levels in lumbosacral spinal cord. Panel B shows 5-HIAA
levels in CSF. There were no differences in 5-HIAA levels in either tissue; however,
there was a trend of decreased 5-HIAA in chronically stressed compared to non-stressed
rats in both spinal cord (p=0.07) and CSF (p=0.075). N=13-15/group.
A
5-HIAA Spinal Cord
14000
12000
5-HIAA (ng/ml)
10000
8000
6000
4000
2000
0
CFS
B
NFS
5-HIAA CSF
14000
12000
5-HIAA (ng/ml)
10000
8000
6000
4000
2000
0
CFS
NFS
71
Figure 5.6. Ratio of 5-HIAA to 5-HT levels in lumbosacral spinal cord and
cerebrospinal fluid. Rats were exposed to footshock (black bars) or no footshock (gray
bars) for 15 min daily for 7 days. Panel A shows 5-HIAA/5-HT levels in lumbosacral
spinal cord. Panel B shows 5-HIAA/5-HT levels in CSF. There were no differences in
5-HIAA/5-HT levels between rats with chronic footshock or no footshock in either tissue.
N=13-15/group.
A
5-HIAA/5-HT Spinal Cord
50
5-HT (ng/ml)
40
30
20
10
0
CFS
B
NFS
5-HIAA/5-HT CSF
500
5-HIAA/5-HT (ng/ml)
400
300
200
100
0
CFS
NFS
72
Figure 5.7. Group mean evoked discharges from dorsal horn neurons in rats with
spinally administered saline or ondansetron. Rats were exposed to footshock or no
footshock for 15 min daily for 7 days. Panels A and B show responses of Type II
neurons to UBD pressures of 20, 40, and 60 mmHg. No significant difference was
observed in neuronal responses with saline (A) or ondansetron (B). Panels C and D show
mean baseline responses of Type II neurons to UBD at 60. A trend of increased baseline
activity was seen in rats with chronic footshock (black bars) treated with saline (C) but
not in ondansetron-treated rats (D). N=7-8/group.
Saline
A
Ondansetron
B
500
500
Footshock
No Footshock
Footshock
No Footshock
400
Group Mean Discharges
Group Mean Discharges
400
300
200
100
300
200
100
0
0
20
40
60
20
Bladder Pressure (mmHg)
Saline
C
Ondansetron
D
400
400
Footshock
No Footshock
Footshock
No Footshock
300
Group Mean Discharges
Group Mean Discharges
40
Bladder Pressure (mmHg)
200
100
0
300
200
100
0
73
60
Figure 5.8. Group mean evoked discharges from dorsal horn neurons. Rats were
exposed to footshock or no footshock for 15 min daily for 7 days, and neuronal activity
was recorded after spinal administration of saline or ondansetron. Panels A and B show
responses of Type II neurons to UBD pressures of 20, 40, and 60 mmHg. No significant
difference was observed between neuronal responses in rats with saline versus
ondansetron after footshock (A) or no footshock (B). Panels C and D show mean
baseline responses of Type II neurons to UBD at 60. A trend of decreased baseline
activity was seen in rats after chronic footshock (C) treated with ondansetron (black bars)
compared to saline (gray bars). No difference in baseline activity was observed after no
footshock (D). N=7-8/group.
A
B
Chronic$
Footshock
500
No$Footshock
500
Saline
Ondansetron
Saline
Ondansetron
400
Group Mean Discharges
Group Mean Discharges
400
300
200
300
200
100
100
0
0
20
40
20
60
C
D
Chronic$
Footshock
400
No$Footshock
400
Saline
Ondansetron
Saline
Ondansetron
300
Group Mean Discharges
Group Mean Discharges
40
Bladder Pressure (mmHg)
Bladder Pressure (mmHg)
200
100
0
300
200
100
0
74
60
Figure 5.9. Electrode depth from spinal cord dorsum (mm). Closed circles indicate
neurons sampled from rats in the chronic footshock group (depth range: 0.3-1.45 mm).
Open circles indicate neurons sampled from rats in the non-footshock group (depth range:
0.16-1.55 mm).
Neuronal Depths
1.8
Distance from Dorsum (mm)
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
CFS
NFS
75
Table 5.1. Statistical analyses of 5-HT, 5-HIAA, and 5-HIAA/5-HT concentrations in
CSF and lumbosacral spinal cord (LS). Tissues were extracted immediately following
chronic footshock or no footshock.
ELISA
5-HT
5-HT
5-HIAA
5-HIAA
5-HIAA/5-HT
5-HIAA/5-HT
Independent Samples t-test
5-HT, 5-HIAA, 5-HIAA/5-HT Concentrations
Chronic Footshock vs. No Footshock
Tissue
df
t
CSF
28
1.087
LS
26
-0.458
CSF
28
-1.922
LS
26
-1.891
CSF
28
-0.891
LS
26
-1.391
76
p-value
0.286
0.651
0.075
0.07
0.380
0.177
CHAPTER 6
DISCUSSION
6.1 Summary of Results
The purpose of the current set of experiments was to further elucidate the
mechanism by which chronic stress potentiates urinary bladder hypersensitivity,
specifically with regard to the role of 5-HT. The experiments contained within this thesis
utilized a different strain of rat than has been previously used in models of bladder pain.
The first set of experiments established the Lewis rat as a model animal for stressinduced bladder hypersensitivity. These experiments also tested the effects of two 5-HT
receptor antagonists on the VMR response to UBD in chronically stressed rats. No
change in abdominal EMG activity was observed with intrathecal WAY 100635 or
ondansetron in either stressed or non-stressed rats. The second set of experiments tested
whether chronic footshock stress altered the levels of 5-HT, 5-HIAA, or 5-HIAA/5-HT.
Surprisingly, there was no increase found in neurotransmitter, metabolite, or the ratio of
the two with chronic stress. If anything, there was a slight decrease in 5-HIAA following
footshock stress. The final set of experiments tested the role of 5-HT3 receptors in the
responses of spinal dorsal horn neurons to UBD in chronically stressed rats. The results
found did not support the hypothesis that an alteration in Type II neurons was involved in
stress-induced bladder hypersensitivity. Furthermore, blockade of spinal 5-HT3
receptors had no bearing on the activity of Type II neurons.
77
6.2 Integration of Findings with Current Literature
6.2.1 The Comorbidity of Stress and Chronic Pain
Pain and stress are similar to the chicken and the egg. It is often hard to discern
which was the precipitating factor. Mayer et al. (2001) described the development and
maintenance of irritable bowel syndrome in terms of risk, trigger, and perpetuating
factors. Risk factors include a genetic predisposition; a pathological, or life-threatening,
stressor; or an early life stressor, such as neglect or abuse. Trigger factors could be a
physical event, such as a surgery or infection, or a psychosocial stressor. Regardless of
the origin, the common thread is that the pain and the anxiety about the pain or other
symptoms perpetuate each other, creating a stress-symptom cycle. This schema can be
applied not only to irritable bowel syndrome but also to many chronic pain
diseases/syndromes, including IC.
There is an increasing awareness of the relationship between chronic pain and
stress or anxiety disorders. A large, randomized study including approximately 6,000
participants conducted using in-home interviews concluded that 35% of people with
chronic pain had a comorbid anxiety disorder, compared to 18% of people in the general
population (McWilliams, Cox, & Enns, 2003). Specific to IC, Rothrock and colleagues
(2001) had 45 patients and 31 healthy matched controls record a daily diary reporting
urinary frequency, urgency, pain, and stress levels. All participants were also required to
complete a Symptom Severity Scale and Perceived Stress Scale. IC patients had
significantly higher reports of stress, both in their diary recordings and on the Perceived
Stress Scale compared to controls. Disease severity was also correlated with a higher
stress level. In a separate survey-based study, women with lower urinary tract symptoms
78
reported lower health-related quality of life compared to women without symptoms, and
of the women with symptoms, 53% fell into the category of having a clinical anxiety
disorder (Coyne et al., 2009).
The correlation between chronic pain and stress can be further examined with
regard to HPA axis function. In a study examining chronic back pain, salivary cortisol
levels were significantly higher in patients compared to controls (Vachon-Presseau et al.,
2013). Interestingly, a group of chronic pain clinic patients and healthy controls were
assessed using the Perceived Stress Scale and had hair cortisol levels measured. The use
of hair samples provides a more long-term account of stress via cortisol levels than
plasma or saliva samples. The chronic pain patients had significantly greater levels of
cortisol in hair samples compared to controls. Pain patients also rated significantly
higher on the Perceived Stress Scale (Van Uum et al., 2008). Patients with fibromyalgia
(which like IC, is a chronic pain syndrome with a diagnosis of exclusion) have a
dysfunctional HPA axis response. For example, they show an reduced stress response,
elevated levels of ACTH, and decreased levels of cortisol and CRF (Lentjes, Griep,
Boersma, Romijn, & de Kloet, 1997). Often there is a loss of circadian rhythmicity of
cortisol in fibromyalgia patients (Crofford et al., 2004). There is a similar loss of
rhythmicity in rheumatoid arthritis patients (Cutolo et al., 2005).
The findings included in this thesis support the previous literature that stress
exacerbates pain in a model of urinary bladder nociception. As a part of the
methodological development, the findings determined that 7 days of footshock stress
produces a robust increase in the magnitude of the VMR response to graded UBD in
Lewis rats. This finding was replicated in Specific Aim 1 in rats with chronic footshock
79
stress and intrathecal saline. While not performed in the same strain of rat, the current
experiments also corroborate previously published findings in Sprague Dawley rats that
chronic footshock stress increases the vigor of VMR responses to UBD compared to rats
that received sham footshock (Black et al., 2009; Robbins & Ness, 2008).
The effect of chronic footshock stress on serum corticosterone levels was also
assessed. Lewis rats exhibited significantly higher levels of corticosterone following 7
days of footshock compared to the sham stress controls. This finding is in line with the
human data demonstrating increased cortisol levels in chronic pain patients (VachonPresseau et al., 2013; Van Uum et al., 2008). Furthermore, this finding is consistent with
the previous report stating that Sprague Dawley rats showed increased plasma
corticosterone levels after 7 days of footshock stress compared to sham controls (Marek
et al., 1992).
6.2.2 Serotonin in Stress-induced Hyperalgesia
While stress-induced hyperalgesia is not a new concept, it has not been a major
focus of basic scientific research. Even fewer reports exist in the literature concerning a
role of 5-HT in stress-induced hyperalgesia. Alosetron, a 5-HT3 receptor antagonist,
became a therapeutic drug of interest in the late 1990’s for its use in irritable bowel
syndrome, a syndrome associated with chronic pain and stress (Camilleri et al., 1999;
Delvaux, Louvel, Mamet, Campos-Oriola, & Frexinos, 1998; Gershon, 1999; Humphrey,
Bountra, Clayton, & Kozlowski, 1999; Mangel & Northcutt, 1999). In animal models of
stress-induced colorectal pain, alosetron administration had beneficial outcomes. Colonic
hyperalgesia induced by water avoidance stress was reversed with intrathecal alosetron
80
(Bradesi et al., 2007). Alosetron, as well as two other 5-HT3 antagonists, ramosetron and
cilansetron, produced a dose-dependent increase in the colonic nociceptive threshold in
rats with restraint stress-induced colonic hypersensitivity (Hirata et al., 2008). Though
more effort needs to be made in determining the effects of 5-HT3 receptors in stressinduced visceral pain, it appears that the 5-HT3 receptor may play a facilitatory role in
colorectal pain. The opposite argument can be made when looking at 5-HT from a broad
perspective. Gameiro et al. (2006) established that temporomandibular joint
hypersensitivity induced by chronic restraint stress was significantly attenuated with
administration of fluoxetine, an SSRI. However, decisive conclusions cannot reasonably
be made with such little data currently available.
The findings included in Specific Aim 1 neither support nor oppose the current
literature reports. Intrathecal ondansetron produced opposite effects in stressed versus
non-stressed rats (significant interaction of Stress x Drug x UBD). While the individual
comparisons of drug versus saline were not significant, ondansetron slightly decreased
VMR responses to UBD in footshock-stressed rats and slightly increased VMR responses
in non-stressed rats. These results do not implicate a facilitatory role of 5-HT3 receptor
activation in stress-induced bladder hypersensitivity, but they also do not carry enough
weight to discredit it. It is possible that alternative results may be found with the use of
other 5-HT3 antagonist compounds.
It appears to be safer to conclude that 5-HT1A receptors are not involved in
chronic stress-induced bladder pain. Intrathecal administration of WAY 100635 in
stressed rats produced no changes in EMG activity in response to UBD. Activation or
inactivation of 5-HT1A receptors may play more of a role in the maintenance of 5-HT
81
levels. This is discussed further in Section 6.3.2. The experiments discussed here
involving blockade of 5-HT1A and 5-HT3 receptors contribute novel findings to the body
of research on stress-induced bladder hypersensitivity.
6.2.3 Dorsal Horn Neuronal Activity in Bladder Pain Models
The spinal neuronal response to bladder distension was previously described in
Section 2.5. Briefly, two populations of neurons were found to respond by increasing
their activity to UBD. Type I neurons are inhibited by HNCS, while Type II neurons are
either not inhibited or excited by HNCS. A series of experiments further differentiated
these two neuron types. Ness and Castroman (2001) demonstrated the analogous
comparison of Type I and II neurons with previously characterized “Abrupt” and
“Sustained” neurons from colorectal experiments (Ness & Gebhart, 2000). Specifically,
Type I neurons have an abrupt cessation of firing after termination of the stimulus, while
Type II neurons have a sustained period of activity following stimulus termination. Type
I/II neurons are also pharmacologically distinct. Type II neuronal activity is inhibited by
intravenous lidocaine or morphine, while Type I activity is not similarly inhibited (Ness
& Castroman, 2001). Intravenous N-methyl-D-aspartate (NMDA) receptor antagonists:
ketamine, dextromethorphan, and memantine produced inhibition of Type I neuron
activity evoked by UBD. The same was not observed in Type II neurons (Castroman &
Ness, 2002).
The distinction between Type I/II has been observed in two models of bladder
pain. In the inflammation-induced bladder pain model, Type II activity was increased
after intravesical zymosan instillation either 2 h or 24 h prior to neuronal recordings.
82
Only in the case where zymosan was applied 24 h prior to testing was a decrease in
activity observed in Type I neurons (Ness et al., 2009). Chronic footshock stress leads to
a significant augmentation of Type II neuronal responses to UBD. This effect was not
similarly observed in Type I neurons (Marek et al., 1992).
Pertaining to the receptive field subclassifications, more WDR than NS neurons
were found in the Type I and Type II population; however, NS neurons were more likely
to be Type II (Ness & Castroman, 2001). Robbins et al. (2011) found that NS neurons
were more likely to be Type II in both decerebrate and intact rats. In spinally intact rats
only, the NS class of neurons was also more likely to be observed in rats that did not
receive footshock stress.
In the current experiments, only Type II neurons were analyzed based on previous
findings that chronic footshock stress showed effects exclusively in Type II (Marek et al.,
1992). The increased UBD-evoked activity of neurons from chronically stressed rats was
not replicated in the current findings. However, it should be noted that there was a trend
of increased activity in stressed rats versus non-stressed rats, but the difference did not
reach statistical significance. Similar to reports from Robbins et al. (2011), the findings
of Specific Aim 3 determined that NS neurons were more likely to be found in rats that
did not receive footshock stress. The current experiments were performed in Lewis rats,
rather than Sprague Dawley, so they also present a new line of research with a different
strain.
Based on the observations in Specific Aim 1 that a greater effect was found on
changes in EMG activity in response to UBD with the 5-HT3 antagonist, ondansetron,
the choice was made to investigate the role of 5-HT3 receptors in Type II neuronal
83
activity in Specific Aim 3. 5-HT3 receptor blockade did not produce any effect on
evoked neuronal responses to graded UBD in stressed or non-stressed rats. These
conclusions provide new evidence on the role of spinal 5-HT in stress-induced bladder
hypersensitivity.
6.3 Discussion of Results
6.3.1 Specific Aim 1
The hypothesis that chronic footshock stress increases abdominal EMG responses
to graded UBD in rats receiving intrathecal saline vehicle was supported in the current
findings. This was expected since the methodological study demonstrated a significant
effect of stress in Lewis rats, and Robbins et al. (2008) previously demonstrated this same
effect in Sprague Dawley rats. These findings support the view that stress alone can
induce bladder hypersensitivity. This is important since the etiology of IC is largely
unknown and many women present with no histological changes (Waxman et al., 1998a).
In the presence of either 5-HT1A or 5-HT3 receptor antagonists, the previously
noted augmentation of EMG responses after chronic footshock stress is not seen. This
finding demonstrates that these receptors are a component of stress-induced bladder
hypersensitivity. In other words, activation of 5-HT1A or 5-HT3 receptors contributes to
stress-induced bladder hypersensitivity. Blockade of either receptor subtype disrupts
normal manifestation of such hypersensitivity; thus activation seems to be required.
Compared to intrathecal administration of saline, WAY 100635 produces a nonsignificant increase in EMG activity in response to UBD in both chronic footshock and
non-footshock treated rats. In contrast to the previous results, this can be interpreted as a
slightly inhibitory role of 5-HT1A receptors in the VMR response to UBD. This
84
inhibitory role appears even more prominent in the tonic, non-stressed state. Intrathecal
ondansetron exerted opposing effects on UBD-evoked VMR responses depending on
whether the rat had been previously exposed to chronic stress or sham stress. While there
was no main effect of ondansetron, there was a significant interaction of Stress x Drug x
UBD. As hypothesized, ondansetron produced a decrease in the VMR response to UBD
in chronically stressed rats. This is not a significant effect, but it does implicate a
possible facilitatory role of the 5-HT3 receptor. Interestingly, ondansetron produced a
non-significant increase in the EMG magnitude of sham-stressed rats similar to that
observed with WAY 100635, therefore also suggesting a tonic inhibition produced by the
5-HT3 receptor, particularly in the non-stressed state. These data suggest that under
normal conditions, activation of the 5-HT3 receptor may inhibit responses to UBD, but
after an inciting event, such as stress, activation of the same receptors may become
facilitatory.
Since the administration of the non-specific 5-HT receptor antagonist,
methysergide, abolishes the stress-induced bladder hypersensitivity effect, there is
evidence that 5-HT has a facilitatory role in the phenomenon. It is possible that due to
the complex nature of the serotonergic system, more than one receptor subtype is
involved. Most likely there is a delicate interplay of a few receptor subtypes that
contributes to stress-induced bladder hypersensitivity. Other spinal 5-HT receptors
involved in the modulation of pain include 5-HT2A/B/C, 5-HT4, 5-HT5A, 5-HT6, and 5HT7. Spinal nerve ligation (a model of neuropathic pain) produces an upregulation of 5HT2A receptors in the spinal cord dorsal horn, which contributes to dorsal horn
hyperexcitability evoked by sciatic nerve C-fiber stimulation (Aira et al., 2012; Aira et
85
al., 2010). The following examples utilize the formalin test, in which formalin is injected
into the hindpaw of the rat and three distinct phases of activity can be observed: initial
phase of activity (0–10 min, phase 1), a quiescent interphase (10–20 min), and a second
phase of activity (20-90 min, phase 2). Both active phases involve ongoing peripheral
afferent neural activity, while an inflammatory response contributes only to phase 2.
Examination of spinal cord tissue revealed increased 5-HT in the ipsilateral dorsal horn
following hindpaw injection of formalin.. Spinal cord tissue used to measure 5-HT
content was dissected from rats immediately after mechanical nociceptive testing, which
was 6 days following formalin injection. Spinal 5-HT depletion by intrathecal 5,7-DHT
prevented formalin-induced hypersensitivity during phase 2 (Godínez-Chaparro, LópezSantillán, Orduña, & Granados-Soto, 2012). Intrathecal administration of 5-HT2B
antagonist, RS-127445, prevented formalin-induced nociception in both phases, while on
the other hand, the 5-HT2 agonist, 2,5-dimethoxy-4-iodoamphetamine (DOI), increased
nociceptive behaviors in the first phase only (Cervantes-Duran et al., 2012). Intrathecal
administration of 5-HT inhibited formalin-induced nociception that was reversed by
intrathecal 5-HT5A antagonist, SB-699551 (Munoz-Islas et al., 2014). In summary, these
studies show that 5-HT2A, 5-HT2B, and 5-HT5A receptors facilitate nociception. In
contrast, it has been reported that intrathecal 5-HT4, 5-HT6, or 5-HT7 agonists prevented
second phase nociception. The reverse was found after intrathecal 5-HT4, 5-HT6, or 5HT7 antagonists were administered (Godínez-Chaparro et al., 2012). These findings
provide evidence of the distinct actions of 5-HT acting at different receptors, adding to
the complexity of serotonergic descending modulation of pain. It is likely that the
facilitation revealed by intrathecal methysergide is not being driven by one receptor
86
subtype. Rather, there is probably a complex balance between inhibition and facilitation
produced by 5-HT at different receptor subtypes, and stress shifts this balance toward
facilitation. This complexity could explain why the non-selective antagonist,
methysergide, prevented stress-induced bladder hypersensitivity, while selective
inhibition of 5-HT1A and 5-HT3 receptors did not.
6.3.2 Specific Aim 2
It was an unanticipated finding that 5-HT levels were not changed after 7 days of
footshock stress. Based on one of the methodological development findings that
intrathecal methysergide produced a significant decrease in the VMR response to UBD in
stressed rats, it was believed that 5-HT was acting in a facilitatory manner in stressinduced bladder hypersensitivity. Therefore, it was expected that chronic stress would
lead to an increase in 5-HT in CSF and/or lumbosacral spinal cord.
5-HIAA is the main metabolite of 5-HT; therefore, as 5-HT is utilized, it is
expected that an increase of 5-HIAA will be observed. The ratio of 5-HIAA to 5-HT
gives an indication of the amount of 5-HT being turned over. Interestingly, there was a
less turnover seen in footshock compared to non-footshock treated rats, although it was
just a slight decrease and was not statistically significant. This finding was unexpected
due to previous reports of increased turnover of 5-HT following stress. For example,
chronic variable stress or chronic restraint stress increased the ratio of 5-HIAA/5-HT in
the hippocampus (Gamaro, Manoli, Torres, Silveira, & Dalmaz, 2003; Torres, Gamaro,
Vasconcellos, Silveira, & Dalmaz, 2002). Acute footshock stress has resulted in
increased 5-HT turnover in prefrontal cortex, thalamus, hypothalamus, hippocampus,
87
brainstem, and, in some cases, striatum (Adell, Trullas, & Gelpi, 1988; Dunn, 1988;
Malyszko et al., 1994). In most of these cases, 5-HT levels were unchanged after stress,
which is why it is important to refer to 5-HT metabolism as a better indicator of activity.
While there is no clear-cut difference in the rate of 5-HT turnover, the results of
Specific Aim 2 reflect those seen in Specific Aim 1. 5-HT may be utilized more by
sham-stressed rats than those receiving footshock stress. This would imply that 5-HT
may have a small, tonic inhibitory influence in sham-stressed rats. The fact that the
levels change at all shows that stress may be disrupting the typical activity of 5-HT.
An absence of a significant alteration in 5-HT levels or rate of turnover after 7
days of stress does not indicate that 5-HT is not involved in stress-induced bladder
hypersensitivity. Even a subtle change in 5-HT levels can impact the activation and/or
expression of a particular 5-HT receptor. For example, 5-HT diminution generally occurs
immediately after a spike in 5-HT release due to 5-HT1A autoreceptor activation. This is
the proposed explanation for the therapeutic lag seen in SSRI use (Celada, Puig,
Amargos-Bosch, Adell, & Artigas, 2004). Systemic administration of the 5-HT1A
agonist, 8-OH-DPAT, resulted in reduced 5-HT release in hippocampus and striatum,
measured by in vivo microdialysis (Kreiss & Lucki, 1994). Using in vitro brainstem
electrophysiology, Le Poul et al. (1995) demonstrated that after 21 days of continuous 5HT1A receptor stimulation, only an 80% desensitization of autoreceptors was observed;
therefore, these receptors maintained the potential to decrease 5-HT release throughout
the study. In the current experiments, it is possible that a longer time course of chronic
stress needed to be utilized in order to overcome 5-HT autoreceptor negative feedback.
88
Rather than increasing 5-HT levels or turnover, stress could augment facilitation
of responses to UBD by altering 5-HT receptor expression or affinity. Quantitative
measures of receptor expression were not assessed in the current studies. A lack of
alteration in neurotransmitter or metabolite may be explained by a change in receptor
expression. It is hypothesized that there would be an upregulation of 5-HT receptors,
especially of 5-HT3. Changes in expression may be found on spinal neurons, dorsal root
ganglia, and/or primary afferent terminals.
6.3.4 Specific Aim 3
It was surprising to find in the current results that chronic footshock did not
increase the activity of Type II neurons in rats with spinally-applied saline. This was
expected based on findings of Robbins et al. (1992) that chronic footshock increased
Type II neuronal activity. However, those experiments were performed in Sprague
Dawley rats; whereas the current experiments were performed in Lewis rats, and
neuronal activity in response to UBD in Lewis has not been tested prior to the current
studies. The inability to replicate the results across rat strains was possibly also due to a
small sample size. Alternatively, this could be a legitimate strain difference, since there
was a trend toward increased neuronal activity in the chronic footshock group with saline,
and this trend was observed in both graded responses and baseline responses.
It is believed that the differentiation of Type I and Type II neurons correlates with
facilitatory and inhibitory mechanisms of pain modulation. Type II neurons are typically
thought to encode excitatory messages of pain perception, while Type I neurons encode
inhibitory messages. This is supported by findings that inflammation- and stress-induced
89
urinary bladder hypersensitivity models show an increased response of Type II neurons to
UBD compared to controls and that this increase is not seen in Type I neurons (Marek et
al., 1992; Ness et al., 2009). The trend of increased Type II activity in chronically
stressed rats most likely also represents an example of facilitation mediated by Type II
neurons. Type I neurons were not tested in the current studies. It is possible that
responses of Type I neurons decrease after stress in Lewis rats, which would decrease
inhibition and therefore contribute to bladder hypersensitivity. It would be important to
note the responsiveness of both neuron types to determine the relationship between the
two.
While searching for UBD-responsive neurons in the dorsal horn, the distinction
had to be made between Type I and Type II. While recordings were not obtained from
Type I neurons, it is important to note that Type I neurons were more readily found in
animals which did not receive footshock, whereas the opposite observation was made in
animals which received chronic footshock. The significance of this imbalance is that
Type I neurons are inhibited by counter-irritation, such as in the phenomenon of DNIC.
In human studies, DNIC is disrupted in patients that suffer from syndromes that are
classified by exclusionary diagnoses (aka ‘functional disorders’), such as fibromyalgia
and irritable bowel syndrome (Lautenbacher & Rollman, 1997; Wilder-Smith et al.,
2004). It is likely that Type I neurons are a key mediator in the DNIC pathway. That
fewer Type I neurons were encountered in stressed rats suggests that an impairment of
DNIC may exist in stress-induced bladder hypersensitivity. Though the responses of
Type II neurons were not altered by chronic stress, the number of Type II neurons could
90
have increased and/or the number of Type I neurons could have decreased, both which
would have increased nociceptive signaling from the dorsal horn.
6.4 Strengths
The current study made use of an existing animal model of urinary bladder
hypersensitivity. However, it did so by introducing and establishing the Lewis strain of
rat in chronic footshock stress-induced bladder hypersensitivity. Elevated serum
corticosterone validated the use of chronic footshock as a stressor in Lewis rats. While
Lewis rats are known to be one of the more anxious strains, evidence of stress-induced
bladder nociception is a novel finding. That there is a less variable increase in abdominal
EMG responses to UBD in the Lewis strain compared to the Sprague Dawley strain
suggests that Lewis rats are a more reliable model of stress-induced bladder
hypersensitivity.
6.5 Limitations
The most striking limitation to the current set of studies lies with the use of
intrathecal catheters to administer spinal drugs. Their use resulted in a diminished EMG
response, irrespective of independent variable grouping. The suppression of all EMG
responses requires there to be a much greater effect size of chronic stress in the
augmentation of EMG response to enable an observable difference. While the effect of
footshock was still evident in rats receiving intrathecal saline, it was considerably smaller
than rats with no disturbances to the intrathecal space.
91
A further limitation was in the sample size. In some cases, statistical significance
may have been achieved by doubling the sample size. However, previous experiments of
similar nature have utilized sample sizes of equal proportions to those used in the current
studies. Unfortunately, increasing the sample sizes to include two times the N was
beyond the scope of this thesis. This is especially true for the electrophysiological
experiments, which were labor-intensive but also restricted to a four-hour maximum
recording time per neuron, including the time allocated for surgical prep. Neurons that
respond to stimulation of the urinary bladder only comprise about 5% of neurons in the
lumbosacral dorsal horn. Occasionally, the search for a UBD-responsive neuron would
exceed the allotted amount of time, and no data could be obtained for a given animal.
Due to the pharmacological nature of the electrophysiology experiments and the
irreversibility or inability to wash out a drug, only one neuron was available for use per
animal. Given these parameters, consideration had to be taken to minimize the use of
laboratory animals.
6.6 Future Directions
Based upon the outcomes of the studies contained within this thesis,
recommendations have been made to further the likelihood of determining the role of 5HT in stress-induced bladder hypersensitivity. The first set of suggested directions
address the issue of a possible lag in 5-HT release and/or accumulation due to 5-HT
autoreceptor sensitization, which may be masking bladder sensitivity. A temporal study
should be undertaken to determine the number of days of footshock at which the greatest
effect on bladder nociception occurs. A suggested design would be to measure the VMR
92
response to UBD after 1, 7, 14, 21, and 28 days of daily footshock stress. In addition to
nociceptive quantification, levels of 5-HT, 5-HIAA, and corticosterone should also be
measured at each time point. Once the optimal footshock period is determined, then the
effect of direct stimulation with 5-HT as well as activation or blockade of receptor
subtypes can be tested. It would be efficacious to perform these experiments, as any
subsequent experiments would rely on the outcome to have the chance of obtaining the
most relevant results.
In an effort to address the unexpected findings in Specific Aim 2 that no changes
in 5-HT or the ratio of 5-HIAA/5-HT were observed following chronic footshock stress,
an alternative study would be to examine the effects of footshock stress on receptor
expression. An ideal set of experiments would measure receptor protein and/or mRNA
levels. The most obvious tissue to analyze would be the spinal cord, specifically at the
thoracolumbar and lumbosacral regions due to their connectivity to the bladder. It would
be worthwhile to also examine receptor expression in the dorsal root ganglia of the above
mentioned spinal cord regions. The exact location of the 5-HT receptors involved in
descending pain modulation at the spinal cord level is unclear. Previously reported 5-HT
receptors that modulate pain following intrathecal activation or blockade include 5HT1A, 5-HT2A/B/C, 5-HT3, 5-HT4, 5-HT5A, 5-HT6, and 5-HT7 (Bardin, 2011;
Cervantes-Duran, Rocha-Gonzalez, & Granados-Soto, 2013; Godínez-Chaparro et al.,
2012; Munoz-Islas et al., 2014; Suwa, Bock, Preusse, Rothenberger, & Manzke, 2014;
Wilder-Smith et al., 2004). Based on the outcome of these quantitative experiments, it
would also be useful to determine the precise location of receptors that are altered with
exposure to chronic stress using immunohistochemistry.
93
Next, to gain a more complete understanding of the spinal physiology of stressinduced bladder hypersensitivity, the activity of Type I spinal dorsal horn neurons should
also be assessed. In most chronic pain conditions, there appears to be a disturbance in the
balance of facilitatory and inhibitory mechanisms. Discerning the activity patterns of
both Type I and Type II neurons and their possible interactions may help to further
elucidate this.
Lastly, it is well known that painful bladder disorders, such as IC, almost
exclusively affect women. This is the indication for using all female subjects in the
current studies. When speculating on the explanation for a sex difference that involves
females being affected, it is most plausible to look to female sex hormones as a
contributing factor. Estrous cycle differences have been documented in inflammationinduced bladder hypersensitivity. Specifically, EMG responses to UBD were
significantly increased during metestrus and proestrus phases compared to estrus and
diestrus in rats with inflamed bladders. No fluctuations as a result of estrous cycle were
observed in non-inflamed rats (Ball, Ness, & Randich, 2010). No data exists on the role
of estrous cycle in stress-induced bladder hypersensitivity; therefore, it would be
advantageous to determine if differences in nociceptive responses relate to phases of the
estrous cycle using the current model.
6.7 Conclusions
The studies conducted within this thesis led to several basic conclusions
pertaining to the study of stress and 5-HT in relation to bladder pain, which can be further
generalized to the understanding of IC. Chronic footshock stress leads to an exacerbation
94
of bladder nociception as evidenced by the VMR response to UBD in Lewis rats.
Chronic footshock stress, as it is currently defined, does not alter the level of 5-HT found
in the lumbosacral spinal cord or CSF. Chronic footshock stress also does not alter the
rate of 5-HT turnover in these tissues. No specific role could be determined for 5-HT3
receptors in rats exposed to chronic footshock stress. There is a facilitatory role of 5-HT
is stress-induced bladder hypersensititivy, but it is not being driven by either 5-HT1A or
5-HT3 receptor activity alone. In light of these findings, it remains unclear which
component of the descending serotonergic system is involved in stress-induced bladder
hyperalgesia.
95
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APPENDIX A
INSTITUTIONAL ANIMAL CARE AND USE COMMITTEE (IACUC)
NOTICE OF APPROVAL
121
THE UNIVERSITY OF ALABAMA AT BIRMINGHAM
Institutional Animal Care and Use Committee (IACUC)
Institutional Animal Care and Use Committee
CH19 Suite 403
933 19th Street South
205.934.7692
FAX 205.934.1188
122
Mailing Address:
CH19 Suite 403
1530 3RD AVE S
BIRMINGHAM AL 35294-0019
$
$
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APPENDIX$B$
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INSTITUTIONAL ANIMAL CARE AND USE COMMITTEE (IACUC)
NOTICE OF APPROVAL FOR PROTOCOL MODIFICATION
123
THE UNIVERSITY OF ALABAMA AT BIRMINGHAM
Institutional Animal Care and Use Committee (IACUC)
Notice of Approval for Protocol Modification
DATE:
April 10, 2013
TO:
MEREDITH T. ROBBINS, Ph.D.
BMR2-270
(205) 975-9684
FROM:
Robert A. Kesterson, Ph.D., Chair
Institutional Animal Care and Use Committee (IACUC)
SUBJECT:
Title: Stress-Induced Bladder Hyperalgesia: A Potential Mediator
Sponsor: NIH
Animal Project_Number: 120608853
On April 10, 2013, the University of Alabama at Birmingham Institutional Animal Care and Use
Committee (IACUC) reviewed the animal use proposed in the above referenced application. It approved
the modification as described: Procedures- chronic catheter implantation. The sponsor for this project
may require notification of modification(s) approved by the IACUC but not included in the original grant
proposal/experimental plan; please inform the sponsor if necessary.
The following species and numbers of animals reflect this modification.
Species
Rats
Use Category
A
Number In Category
Zero - Procedural
modification only
Rats
B
Zero - Procedural
modification only
Rats
C
Zero - Procedural
modification only
The IACUC is required to conduct continuing review of approved studies. This study is scheduled for
annual review on of before June 26, 2013. Approval from the IACUC must be obtained before
implementing any changes or modifications in the approved animal use.
Please keep this record for your files.
Refer to Animal Protocol Number (APN) 120608853 when ordering animals or in any correspondence
with the IACUC or Animal Resources Program (ARP) offices regarding this study. If you have concerns
or questions regarding this notice, please call the IACUC office at (205) 934-7692.
Institutional Animal Care and Use Committee (IACUC)
CH19 Suite 403
933 19th Street South
(205) 934-7692
FAX (205) 934-1188
$
124
Mailing Address:
CH19 Suite 403
1530 3rd Ave S
Birmingham AL 35294-0019