Download Regulation of respiration

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Neuroeconomics wikipedia , lookup

Caridoid escape reaction wikipedia , lookup

Mirror neuron wikipedia , lookup

Metastability in the brain wikipedia , lookup

Clinical neurochemistry wikipedia , lookup

Neural oscillation wikipedia , lookup

Syncope (medicine) wikipedia , lookup

Neural coding wikipedia , lookup

Stimulus (physiology) wikipedia , lookup

Neuroanatomy wikipedia , lookup

Nervous system network models wikipedia , lookup

Synaptic gating wikipedia , lookup

Development of the nervous system wikipedia , lookup

Haemodynamic response wikipedia , lookup

Feature detection (nervous system) wikipedia , lookup

Central pattern generator wikipedia , lookup

Neuropsychopharmacology wikipedia , lookup

Premovement neuronal activity wikipedia , lookup

Optogenetics wikipedia , lookup

Circumventricular organs wikipedia , lookup

Channelrhodopsin wikipedia , lookup

Pre-Bötzinger complex wikipedia , lookup

Transcript
Regulation of respiration
„
Breathing is controlled by the central
neuronal network to meet the metabolic
d
demands
d off th
the b
body
d
– Neural regulation
– Chemical regulation
Respiratory center
„
Definition:
– A collection of functionally similar neurons
that help to regulate the respiratory movement
Respiratory center
„
Medulla
„
P
Pons
„
Higher respiratory center: cerebral cortex
cortex,
Basic respiratory center: produce
and control the respiratory
rhythm
hypothalamus
ypot a a us & limbic
b c system
syste
„
Spinal
p
cord: motor neurons
Neural regulation of respiration
„
Voluntary breathing center
– Cerebral cortex
„
Automatic (involuntary) breathing center
– Medulla
– Pons
Neural generation of rhythmical
breathing
The discharge of
medullary inspiratory
neurons provides rhythmic
input to the motor neurons
innervating the inspiratory
muscles. Then the action
potential
t ti l cease, th
the
inspiratory muscles relax,
and expiration occurs as
the elastic lungs recoil.
„
Inspiratory
neurons
„
Expiratory
p
y
neurons
Respiratory center
„
Dorsal respiratory group (medulla) – mainly
causes inspiration
p
„
Ventral respiratory group (medulla) – causes
either
ith expiration
i ti or iinspiration
i ti
„
Pneumotaxic center ((upper
pp p
pons)) – inhibits
apneustic center & inhibits inspiration,helps
control the rate and pattern of breathing
„
Apneustic center (lower pons) – to promote
inspiration
Hering-Breuer inflation reflex
(Pulmonary stretch reflex)
„
The reflex is originated in the lungs and
mediated
di t d b
by th
the fib
fibers off th
the vagus nerve:
– Pulmonary inflation reflex:
ƒ inflation of the lungs, eliciting expiration.
– Pulmonary inflation reflex:
ƒ deflation,
deflation stimulating inspiration
inspiration.
Pulmonary inflation reflex
„ Inflation
of the lungs → +pulmonary
stretch receptor →+vagus nerve → medually inspiratory neurons →
+eliciting expiration
e piration
Chemical control of respiration
„
Chemoreceptors
– Central chemoreceptors: medulla
ƒ Stimulated by [H+]↑ in the CSF
– Peripheral chemoreceptors
ƒ Carotid body
– Stimulated by arterial PO2↓ or [H+]↑
ƒ Aortic body
Central chemoreceptors
Peripheral chemoreceptors
Chemosensory neurons
that respond to changes
in blood pH and gas
content are located in
the aorta and in the
carotid sinuses; these
sensory afferent
neurons alter CNS
regulation
l ti off
the rate of ventilation.
Effect of carbon dioxide on
pulmonary
l
ventilation
il i
Small changes in the
carbon dioxide content
of the blood quickly
trigger changes in
ventilation rate.
rate
CO2 ↑ → ↑ respiratory activity
Central and peripheral
chemosensory neurons
that respond to increased
carbon dioxide levels in
the blood are also
stimulated by the acidity
from carbonic acid
acid, so
they “inform” the
ventilation control center
in the medulla to increase
the rate of ventilation.
CO2+H2O → H2CO3 → H++HCO3-
Effect of hydrogen ion on
pulmonary
l
ventilation
il i
[H+] ↑ → ↑ respiratory activity
Regardless
of the source,
increases in
the acidity of
th bl
the
blood
d cause
hyperventilation.
Regardless of the source,
increases in the acidityy of
the blood cause
hyperventilation, even if
carbon dioxide levels are
driven to abnormally low
l
levels.
l
Effect of low arterial PO2 on
pulmonary
l
ventilation
il i
PO2 ↓ → ↑ respiratory activity
A severe reduction in the arterial concentration of
oxygen in the blood can stimulate hyperventilation.
Chemosensory neurons
that respond to decreased
oxygen levels in the blood
“inform” the ventilation
control center in the
medulla
d ll tto iincrease th
the rate
t
of ventilation.
In summary:
The levels of
oxygen carbon
oxygen,
dioxide, and
hydrogen ions
in blood and CSF
provide information
that alters the
rate of ventilation.
Regulation of respiration