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Transcript
Chapter 10
Central Nervous
System, Spinal
Nerves, and Cranial
Nerves
Copyright 2010, John Wiley & Sons, Inc.
Spinal Cord Structure: Protection and
Coverings


Vertebrae
Spinal meninges

Three layers of connective tissue





Dura mater
Arachnoid mater
Pia mater
Continuous with cranial meninges
Cerebrospinal fluid (CSF)
Copyright 2010, John Wiley & Sons, Inc.
Spinal Meninges and Spaces


Epidural space: between vertebrae and dura
mater
Dura mater- tough ,dense connective tissue


Arachnoid mater: resembles spider’s web


Extends into subarachnoid space
Subarachnoid space


Extends to vertebra S2 (well beyond spinal cord)
CSF circulates in this space
Pia mater: thin, delicate layer


Adheres to surface spinal cord (and brain)
Contains blood vessels
Copyright 2010, John Wiley & Sons, Inc.
Spinal
Meninges
and Spaces
Copyright 2010, John Wiley & Sons, Inc.
Gross Anatomy of Spinal Cord


Extends from medulla of brain to L2 vertebra
Cauda equina (horse’s tail)



Left and right halves partially separated by



Extends inferior to end of spinal cord
Consists of roots of lumbar, sacral and coccygeal
spinal nerves
Anterior median fissure and posterior median
sulcus
Small central canal (filled with CSF) in middle
Enlargements: cervical and lumbar regions

Points of origins of nerves to upper and lower limbs
Copyright 2010, John Wiley & Sons, Inc.
Gross
Anatomy of
Spinal Cord
Copyright 2010, John Wiley & Sons, Inc.
Spinal nerves & plexi



After emerging from spinal cord, each spinal nerve divides into
dorsal and ventral rami
- rami contain both, efferent motor and afferent sensory fibers
- smaller dorsal rami serve the skin and muscles of the posterior
body trunk
- larger ventral rami of spinal nerves T2 - T12 pass anteriorly as
intercostal nerves; supply muscles of the intercostal spaces,
the skin and muscles of the anterior and lateral trunk;
Ventral rami of all other spinal nerves form complex nerve networks
called plexi; serve the motor and sensory needs of the upper and
lower limbs.
4 major nerve plexi are found, which are:
1. Cervical plexus
2. Brachial plexus
3. Lumbar plexus
4. Sacral plexus
Cervical Plexus



Arises from the ventral rami of C1 - C5
Supplies muscles of the shoulder and neck
Major motor branch is the phrenic nerve
- arises from C3 - C5
- innervates the diaphragm
"The primary danger of a 'broken neck' is that the
phrenic nerve may have been severed, leading to
paralysis, cessation of breathing and death ..."
Brachial Plexus


Arises from ventral rami of C5 - C8, and T
Subdivides into 5 major peripheral nerves which are:
1. Axillary nerve
- serves the muscles and skin of the shoulder, e.g. deltoid muscle
- damage causes paralysis and atrophy of deltoid
2. Radial nerve
- large peripheral nerve which innervates all extensor muscles of
arm, forearm and hand; and all the skin along the way;
- e.g. triceps brachialis
- damage causes wrist drop and inability to extend hand
3. Median nerve
- runs down anterior of the arm
- supplies most of the flexor muscles in the forearm and several
muscles in the lateral part of the hand;
- damage causes inability to pick up small objects due to
decreased ability to flex and abduct thumb and index finger;
Lumbar Plexus



Arises from the central rami of L1 - L4
Innervates the lower abdominal region and the
anteromedial thigh
Largest nerve of this plexus is the femoral nerve;
- innervates the anterior thigh muscles, lower abdomen, buttocks,
and the skin of the anteromedial leg and thigh;
- damage causes inability to extend leg and to flex the hip;

Other important nerve is the obturator nerve;
- innervates the adductor muscles of the medial thigh and small hip
muscles; also serves the skin of the medial thigh and hip joint;
- damage leads to inability to adduct the thigh;
Sacral Plexus


Arises from L4 - S4; peripheral nerves innervate buttock,
posterior thigh and virtually all of the leg and foot
Major nerve is the sciatic nerve;
- the largest nerve of the human body!
- travels through the greater sciatic notch of hip bone down to the
posterior thigh;
- innervates lower trunk and posterior surface of thigh and leg;
- damage leads to inability to extend hip and to flex the knee
--> "sciatica“
- divides in the popliteal region into the:
1. Common fibular nerve
- innervates the lateral aspect of the leg and foot;
- damage leads to inability to dorsiflex the foot --> "footdrop"
2. Tibial nerve
- innervates the posterior aspect of the leg and foot;
- damage: inability to plantar flex and invert foot --> "shuffling
gait";
Internal Structure of Spinal Cord

Gray matter forms “H” (or “butterfly”)

Three horns on each side; sites of cell bodies




Posterior gray horns: contain sensory neurons
Anterior gray horns: contain somatic motor neurons
Lateral: contain autonomic motor neurons
White matter (surrounds gray “H”)

Consists of white columns


Posterior, anterior, and lateral columns
Contain tracts (bundles of axons)
Sensory tracts: ascending to brain
 Motor tracts: descending from brain

Copyright 2010, John Wiley & Sons, Inc.
Internal Structure of Spinal Cord
Copyright 2010, John Wiley & Sons, Inc.
Spinal Nerves

31 pairs




Named according to level of vertebra
C1-C8, T1-T12, L1-L5, S1-S5, 1 coccygeal
Emerge from spinal cord through intervertebral
foramina
Nerves attached to spinal cord by 2 roots

Dorsal root: made of axons of sensory neurons


Dorsal root ganglion: swelling containing cell bodies of
sensory neurons
Ventral root: composed of axons of motor neurons

Both somatic motor and autonomic motor
Copyright 2010, John Wiley & Sons, Inc.
Spinal Nerve Composition


Formed by 2 spinal nerve roots
Are mixed:


Formed from dorsal root (sensory) and ventral
root (motor) root
Connective tissue coverings



Individual axons wrapped in endoneurium
Axons grouped in fascicles wrapped in
perineurium
Outer covering = epineurium
Copyright 2010, John Wiley & Sons, Inc.
Spinal Nerve Composition
Copyright 2010, John Wiley & Sons, Inc.
Distribution of Spinal Nerves




Spinal nerves branch after pass through
intervertebral foramina
Some join with branches from neighboring
nerves to form plexuses
Nerve names relate to region innervated
Spinal nerves T2-T12 do not form plexuses


Called intercostal nerves
Supply abdominal muscles, skin of chest and
back, and muscles between ribs.
Copyright 2010, John Wiley & Sons, Inc.
Spinal
Cord
Copyright 2010, John Wiley & Sons, Inc.
Spinal Cord Functions

Pathways for nerve impulses within tracts



Ascending (sensory). Example: spinothalamic
Descending (motor). Example: corticospinal
Reflexes: fast, involuntary sequences of
actions in response to stimuli


Can be simple (withdrawal) or complex (learned
sequence such as driving car)
Levels


Spinal (reflex arc): simple
Cranial: more complex
Copyright 2010, John Wiley & Sons, Inc.
Reflex Arc
1. Sensory receptor: responds to stimulus
2. Sensory neuron: through dorsal root
ganglion and root  posterior horn
3. Integrating center: single synapse
between sensory and motor neurons
4. Motor neuron: from anterior horn 
ventral root  spinal nerve 
5. Effector: muscle responds
Copyright 2010, John Wiley & Sons, Inc.
Example of Reflex Arc: Patellar Reflex
1. Sensory receptor is stimulated by tap on
patellar tendon
2. Sensory neuron: through dorsal root 
spinal cord
3. Integrating center: single synapse in
spinal cord
4. Motor neuron: through ventral root 
spinal nerve  femoral nerve 
5. Effector: quads contract, extend leg
Copyright 2010, John Wiley & Sons, Inc.
Example of Reflex Arc: Patellar Reflex
Reflex is a very fast involuntary sequence
of actions in the body in response to a
particular stimulus; some reflexes, e.g. the
eye lid or patellar knee jerk reflex, are
inborn and don't have to be trained
Copyright 2010, John Wiley & Sons, Inc.
Examples of important reflexes

1. Patellar (or knee jerk) reflex
- assesses the function of the S1 and S2 spinal nerves;
- sensory receptors and effector are the quadriceps femoris
2. Plantar reflex
- neurological test whih probes the integrity of the
corticospinal tract (= major voluntary motor tract);
- elicited by stimulating receptors in the sole of the foot;
- effector muscles are flexor muscles in toes which flex and
move close together;
- damage to corticospinal tract elicits "Babinski's sign";
- as consequence the toes flare and the great toe moves upward!
3. Eye lid reflex
4. Corneal reflex
- tests normal functioning of trigeminal nerve ( cranial nerve V);
- absence of reflex often indicates damage to brain stem;
Examples of important reflexes

5. Gag reflex
- tests the normal motor responses of the cranial nerves IX & X
(= vagus);
- receptors are in oral mucosa on the side of uvula;
- effector function (= response) is the rise of the oral mucosa;
- absence of reflex often indicates damage to the brain stem;
6. Pupillary light reflex
- retina of the eye is the receptor; many CNS centers involved
- tests function of the sensory (afferent) optic nerve
(= cranial nerve I) and of efferent oculomotor nerve
(= cranial nerve III)
- effector muscles are smooth muscles of the iris;
- absence of reflex is late indication of severe trauma or
deterioration of the brain stem;
Brain: Major Parts

Brain stem (BS): continuous with spinal cord


Diencephalon (DE): superior to brain stem



Surface covered with gray matter: cortex
Deep to cortex is cerebral white matter
Cerebellum (CB): posterior and inferior


Thalamus, hypothalamus, and pineal gland
Cerebrum (C): largest part and most superior


Medulla oblongata, pons, midbrain
Means “little brain”
Cranial meninges: dura mater, arachnoid
mater, and pia mater
Copyright 2010, John Wiley & Sons, Inc.
Brain: Major Parts
Limbic cortex
Copyright 2010, John Wiley & Sons, Inc.
Corpus callosum
Brain: Major Parts
Copyright 2010, John Wiley & Sons, Inc.
Brain Blood Supply and Blood-Brain
Barrier

Requires 20% of the body’s O2 supply



Requires continuous glucose supply
Protected by blood-brain barrier



4 min lack  permanent brain damage
Allows passage of lipid soluble materials: O2,
CO2, alcohol, anesthetic agents
But controls entry of most harmful materials
Created by tight capillaries and astrocytes
Copyright 2010, John Wiley & Sons, Inc.
Cerebrospinal Fluid (CSF)

Formed in the 4 ventricles of brain


Lateral (#1 and 2)  3rd  4th ventricle
Formed in choroid plexuses



Pathway



By filtration and secretion of blood plasma
In specialized capillary networks (covered by ependymal
cells) in walls of ventricles
Through 4 ventricles  central canal of spinal cord
and within subarachnoid space 
Reabsorbed through arachnoid villi into blood in
superior sagittal sinus
Cushions brain and provides nutrients
Copyright 2010, John Wiley & Sons, Inc.
Cerebrospinal
Fluid (CSF)
Copyright 2010, John Wiley & Sons, Inc.
Brain Stem: Medulla Oblongata

Most inferior part of brainstem


White matter connects spinal cord and other parts
of brain
Contains vital nuclei

Cardiovascular center


Medullary rhythmicity area



Regulates heart rate, blood pressure
Adjusts respiratory rhythm
Other sensory and reflex motor areas
Cranial nerves VIII-XII attached here
Copyright 2010, John Wiley & Sons, Inc.
Brain Stem: Pons

Serves as a “bridge”




Connects medulla to midbrain and above
Contains ascending and descending tracts
Connects left and right sides of cerebellum
Contains nuclei



Motor relays from cerebrum to cerebellum
Helps control breathing
Cranial nerves V-VIII attached here
Copyright 2010, John Wiley & Sons, Inc.
Brain
Stem
Copyright 2010, John Wiley & Sons, Inc.
Brain Stem: Midbrain

Connects pons to diencephalon


Large tracts: cerebral peduncles
Nuclei:




Substantia nigra: related to Parkinson disease
Red nuclei: help coordinate movements
Origin of cranial nerves III and IV (control eye
movements)
Superior colliculi: nuclei involved in



Scanning eye movements
Responses to visual stimuli
Inferior colliculi: responses to auditory input
Copyright 2010, John Wiley & Sons, Inc.
Reticular Formation



Netlike arrangement of gray and white matter
Contains ascending and descending tracts
Ascending part = reticular activating system
(RAS)



Carries sensory pathways to cerebral cortex
Helps maintain consciousness
Helps induce sleep
Copyright 2010, John Wiley & Sons, Inc.
Reticular Formation
Copyright 2010, John Wiley & Sons, Inc.
Diencephalon

Thalamus: major sensory relay center


Hypothalamus: lies inferior to thalamus







Also motor, autonomic, and consciousness
functions
Control of pituitary and hormone production
Works with ANS regulating many viscera
Involved with feelings and behavior patterns
Regulation of eating, drinking, fluid levels
Control of body temperature
Regulation of circadian rhythms, sleep, waking
Pineal gland: secretes melatonin

Controls sleep, biological clock
Copyright 2010, John Wiley & Sons, Inc.
Diencephalon
Copyright 2010, John Wiley & Sons, Inc.
Cerebellum

Location: posterior to medulla and pons,
inferior to cerebrum


Attached to brain stem by cerebellar peduncles
Structure:



Two cerebellar hemispheres
Cerebellar cortex: gray matter
Tree-like appearance (seen in sagittal section) of
white matter and gray nuclei
Copyright 2010, John Wiley & Sons, Inc.
Cerebellum

Functions





Receives wide range of sensory input from
muscles, joints, tendons, eyes, inner ears
Compares actual movements with intended ones
Helps produce smooth, coordinated movements
Helps execute skilled motor activities
Regulates posture and balance
Copyright 2010, John Wiley & Sons, Inc.
Cerebrum: Structure







Cerebral cortex
Internal white mater
Deep gray nuclei
Surface folds of cerebral cortex: gyri
Grooves between gyri: sulci
Longitudinal fissure: divides cerebrum into
left and right hemispheres
Hemispheres connected by corpus collosum
Copyright 2010, John Wiley & Sons, Inc.
Cerebrum: Structure

Each hemisphere has 4 lobes





Frontal, parietal, temporal, occipital
Central sulcus separates frontal, parietal
Precentral gyrus anterior to sulcus: primary motor
area
Postcentral gyrus: primary somatosensory area
Deep gray nuclei: basal ganglia

Globus pallidus, putamen, caudate nucleus
Copyright 2010, John Wiley & Sons, Inc.
Cerebrum
Copyright 2010, John Wiley & Sons, Inc.
Cerebrum
Copyright 2010, John Wiley & Sons, Inc.
Limbic System




Ring of structures on inner border of
cerebrum and floor of diencephalon
Called “emotional brain”: plays primary role
in pain, pleasure, anger, affection and in
behavior
Involuntary activity related to survival
Important in memory development
Copyright 2010, John Wiley & Sons, Inc.
Limbic System


"Seat" of the "emotional brain”
Role in control of a range of emotions (pain, pleasure,
affection, anger), appetite, emotions, and memory
- electric stimulation of some limbic areas triggers reactions of anger,
anxiety, excitement, sexual interest , colorful visions and relaxation;

Consists of:
1. Amygdala
- associated with aggressive behavior
- allows distinction between positive and negative memories;
2. Hippocampus
- "Seat" of the long-term memory of the brain;
- loss of nerve functions in this region observed in AD patients;
3. Transparent septum  associated with pleasure
4. Cingulate gyrus
5. Maxillary bodies  role in creation of memory;
Limbic System
Copyright 2010, John Wiley & Sons, Inc.
Limbic System
Functional Areas of Cerebral Cortex




Specialized areas in specific regions of
cerebral cortex
Sensory areas receive input  perception
Motor areas  initiate movements
Associative areas  complex integration:
memory, emotion, reasoning, judgment
Copyright 2010, John Wiley & Sons, Inc.
Sensory Areas

Primary somatosensory area: postcentral
gyrus





Input includes: touch, proprioception, pain, itching, tickle,
temperature
Primary visual area: occipital lobe
Primary auditory area: temporal lobe
Primary gustatory (taste) area: base of
postcentral gyrus
Primary olfactory (smell) area: medial aspect
of temporal lobe
Copyright 2010, John Wiley & Sons, Inc.
Motor Areas



Located anterior to central sulcus
Primary motor area: precentral gyrus
Broca’s speech area


Interacts with premotor area and primary motor
area to regulate breathing and speech muscles
Is in left hemisphere in 97% of persons
Copyright 2010, John Wiley & Sons, Inc.
Association Areas



Adjacent to sensory and motor areas and
connected via association tracts
Integrate and interpret information
Examples

Somatosensory association area



Posterior to primary somatosensory area
Integrates sensation: exact shape and texture of object
compared with stored memories
Wernike’s area: left temporal, parietal lobes


Interprets meaning of speech: words  thoughts
Right hemisphere adds emotional content
Copyright 2010, John Wiley & Sons, Inc.
Cerebrum: Functional Areas
Copyright 2010, John Wiley & Sons, Inc.

Hands, feet and face are over-proportionally represented in the
sensory (“tactile”) cortex

Hands and face (especially lips and tongue) are overproportionally represented in the motor cortex
Somatic Sensory Pathways


Relay sensory information from periphery to
cerebral cortex
3 neurons in each pathway




Cell body #1 in dorsal root ganglion
Cell body #2 in spinal cord or brain stem
Cell body #3 in thalamus; axon extends to
cerebral cortex (somatosensory area in
postcentral gyrus)
Most sensory input to right side of body
reaches left side of brain (and vice versa)
Copyright 2010, John Wiley & Sons, Inc.
Somatic Sensory Pathways

Posterior column - medial lemniscus pathway
senses




Fine touch: body location, texture, size
Proprioception: position and motion of body parts
Vibrations: fluctuating touch stimuli
Spinothalamic pathways


Anterior and lateral spinothalamic tracts
Relay impulses for pain, tickle, itch, hot, and cold
sensations
Copyright 2010, John Wiley & Sons, Inc.
Somatic
Sensory
Pathways
Copyright 2010, John Wiley & Sons, Inc.
Somatic Motor Pathways

Signals come from





Upper motor neurons: via corticospinal tracts
Basal ganglia: help with muscle tone
Cerebellum: coordination
Sensory neurons or interneurons via reflexes
Impulses activate lower motor neurons


Cell bodies in anterior gray of spinal cord
Axons  ventral root  spinal nerve  muscle 
voluntary movements
Copyright 2010, John Wiley & Sons, Inc.
Somatic Motor
Pathways
Copyright 2010, John Wiley & Sons, Inc.
Somatic Sensory and Motor Pathways
Interactions Animation

Somatic Sensory and Motor Pathways
You must be connected to the internet to run this animation.
Copyright 2010, John Wiley & Sons, Inc.
Lateralization

Brain controls opposite side of the body: all
sensory and motor pathways cross in CNS




Left side of the brain controls right side of body
Right side of brain controls left side of body
Left hemisphere important for spoken and
written language, numerical and scientific
skills, and reasoning
Right side more involved with spatial and
pattern recognition and emotional content
Copyright 2010, John Wiley & Sons, Inc.
Motor pathway pathology


"Damage or disease (e.g. viruses) of LOWER MOTOR
NEURONS leads to flaccid paralysis of muscles on the
SAME SIDE of the body. Under these conditions,
muscles lack voluntary control and reflexes; the muscles
remain flaccid (limp) due to decreased or lost muscle
tone.
Injury or disease of UPPER MOTOR NEURONS causes
spastic paralysis of muscles located on the opposite
side of the body; in this condition the muscle tone is
increased, reflexes are exaggerated, and pathological
reflexes appear."
Memory




Process for storing and retrieving information
Involves structural and functional changes
Involves association areas, parts of limbic
system, and diencephalon
Skill memory also involves cerebellum and
basal ganglia
Copyright 2010, John Wiley & Sons, Inc.
Cranial Nerves (Table 10.2)
I. Olfactory: special sensory—smell
II. Optic: special sensory—vision
III. Oculomotor: motor—control of eye
movements
IV. Trochlear: motor—control of eye movements
V. Trigeminal: mixed
 General
sensory: touch, pain, pressure, hot,
cold in face
 Motor: to muscles used for chewing
Copyright 2010, John Wiley & Sons, Inc.
Cranial Nerves
VI. Abducens: motor—control of eye
movements
VII.Facial: mixed


Special sensory (taste) from anterior of tongue
Motor to muscles of facial expression, tear
glands, and some salivary glands
VIII.Vestibulocochlear: special sensory—ear
Copyright 2010, John Wiley & Sons, Inc.
Cranial Nerves
IX. Glossopharyngeal: mixed


Sensory for posterior of tongue, pharynx, and
palate; blood pressure
Motor to pharyngeal muscles (swallowing),
salivary gland (parotid
Copyright 2010, John Wiley & Sons, Inc.
Cranial Nerves
X. Vagus: mixed (the major parasympathetic
nerve)


Sensory from pharynx, ear, diaphragm,
visceral organs in thoracic and abdominal
cavities
Motor to palatal and pharyngeal muscles
(swallowing and voice); to viscera in thoracic
and abdominal cavities
Copyright 2010, John Wiley & Sons, Inc.
Cranial Nerves
XI. Accessory: motor to voluntary muscles
including sternocleidomastoid and trapezius
(move head, shoulders)
XII.Hypoglossal: motor to tongue (swallowing
and speech)
Copyright 2010, John Wiley & Sons, Inc.
Aging

Rapid brain growth during first few years of
life



Due to increase in size of neurons and
proliferation of neuroglia
Increase in development of dendritic branches
and synaptic contacts
From early adulthood through old age:



Decline in brain mass
Fewer synaptic contacts brain function
Some decrease in brain function
Copyright 2010, John Wiley & Sons, Inc.
Neuropathology – Disease &
disorders affecting CNS & PNS
Neurology
Scientific study of nerve tissue & brain function
Neurogenesis
Biological process through which new neurons are created;
very limited in the adult human brain
Neuralgia
Severe pain that occurs along a nerve with unknown cause;
may occur as repeated stabs of pain in the teeth, sinuses, eyes,
tongue, face, or throat; occurs most frequently in two CN
1. Trigeminal nerve (= CN V)
- pain in eyes, face, sinuses, and teeth
2. Glossopharyngeal nerve (= CN IX)
- pain in the back of tongue and throat
Copyright 2010, John Wiley & Sons, Inc.

Hydrocephalus
Painful brain abnormality characterized by elevated
CSF pressure of the brain;
Due to defective or blocked drainage of the CSF from
the ventricles into the subarachnoid space and the
resulting fluid build-up;

Ataxia
muscle coordination disorder
caused by traumatic, drug or
disease damage to the cerebellum;
people cannot touch the tip of their
nose; changed speech pattern due
to uncoordinated speech muscles;
symptoms are staggering or abnormal walking

Prion diseases
Rare and fatal human neurodegenerative disorder;
includes variant Creutzfeld-Jacob disease and KuruKuru.
Brain tissue appears “spongy”
with holes.
Can appear sporadic, dominantly
heritable and in transmissible
forms (e.g. BSE and Scrapie).
Cause and pathogenic mechanism
still unknown.
Scientists have evidence that an
infectious and protease-resistant version (PrPSC) of a
brain-specific protein called prion (PrP) plays a pivotal
role in the outbreak of the disease.

Parkinson's disease (PD)
Progressive neurodegenerative disorder.
Patients show uncontrollable shaking and movement
disruptions due to nerve cell degeneration of neurons
that extend from the substantia nigra, to the putamen
and caudate nucleus.
PD is characterized by accumulation of protein tangles
and plaques (= Lewis bodies) in
damaged neurons.
Protein plaques contain fibrils of
mutated protein called α-synuclein.
PD patient brain biopsies show cell death of
dopaminergic neurons located in the substantia nigra of
the brain.
Patients show inability to control and stop certain
movements (dyskinesias) and other motor dysfunctions
Treatment: dopamine precursor molecule L-Dopa
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Shingles
Acute infection of the PNS caused by the Herpes
zoster virus, which homes into the posterior root
ganglion.
The reactivated virus interferes with the normal function
of sensory axons to the skin;
pain, skin discoloration and
characteristic line of skin
blisters.
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MDMA & Ecstacy
MDMA stands for the chemical methyl-enedioxymethamphetamine, which is used to make the illegal
“fashion” drug Ecstasy.
MDMA is a derivative of the common, legal drug
methamphetamine, a chemical that has been reported
to have destructive effects on dopaminergic neurons of
primate brains.
Some scientists believe that there is a connection
between "Met" overuse and predisposition to Parkinson
disease (PD) development in later years.