BMS 200 - Sleep, Part 1 Fall 2023 PDF

Summary

This document contains lecture notes on sleep physiology and selected sleep disorders. It covers topics such as neuroanatomy, melatonin synthesis, sleep architecture, and sleep disorders like sleep apnea and narcolepsy.

Full Transcript

BMS 200 – Sleep, part 1

Physiology of Sleep and Selected Sleep Disorders
Objectives
Describe the relevant neuroanatomy in the context of physiology
and regulation of sleep and wake states
Integrate the biochemistry of melatonin synthesis with
environmental factors such as light exposure, and other
physiological factors such as external temperature
Define sleep architecture, including stages of sleep, REM sleep,
and the different brain waves that characterize them
Describe the etiology and pathophysiology of sleep apnea
Describe the etiology and pathophysiology of narcolepsy and
cataplexy
Describe the etiology and pathophysiology of restless leg
syndrome
Describe the pathophysiology of parasomnia's including night
terrors and sleepwalking
What is sleep, and why does it happen?
Surprisingly difficult question to answer, despite
the fact it constitutes 1/3 of our lives
▪ Disruption of sleep increases the risk of stroke,
hypertension, and coronary artery disease
Disrupted breathing during sleep elevates these risks
▪ Only about 30% of adults in NA report getting enough
sleep, and 50% report that their sleep is disturbed
▪ Sleep deprivation degrades cognitive performance, and
deeper (Stage III/IV, or N3 sleep) sleep seems to be more
critical
Experimentally, adults can be deprived of REM sleep
with little in the way of psychologic consequences
 How do we measure sleep… or
wakefulness?
Polysomnography is used to measure the
states of wakefulness → sleep
▪ EEG (electroencephalogram) –
surface electrodes that are attached
to the skull
▪ EMG (electromyogram) – electrodes
attached to skeletal muscle – face and
legs, usually
▪ EOG (electrooculogram) – electrodes https://en.wikipedia.org/wi
measure eye movements ki/File:Polysomnography_te
ster.jpg
▪ Often ECGs and pulse oximeters will
be attached as well, to determine
oxygenation and cardiac function
 What does an EEG measure?
Your cortex is organized in 6 major
layers – the largest and one of the
most prevalent cells in those layers is
the pyramidal cell
▪ Apical dendrites are localized closest
to the skull
▪ The axon is deeper down, and
travels to a variety of targets
including the white matter and
descending tracts
Since the very large dendrites are
closest to the electrode,
measurements usually reflect
differences in potential between the
dendrite and cell body…
▪ They don’t seem to directly measure
action potentials
EEGs and “states of consciousness”
EEGs leads measure two major things in the underlying cortex
▪ Frequency of potentials (rhythms or waves, in Hz)
▪ Size of waves (in uV)
When you have your eyes closed and your mind wanders, you
have waves that are known as the alpha rhythm
▪ 8-13 Hz, “medium amplitude” waves
When you open your eyes and are wide awake, then you exhibit
what is known as the beta rhythm
▪ 13 – 30 Hz, “low amplitude” waves
When awake, the ECG waves don’t usually show regular waves
and look “random” - REM sleep looks “random” too
When sleeping, regular patterns/waveforms can be discerned
▪ Known as synchronized sleep (awake/REM is known as dys-
synchronized)
 EEGs and “states of consciousness”
EEG records showing the
alpha and beta rhythms.
When attention is
focused on something,
the 8–13 Hz alpha
rhythm is replaced by an
irregular 13–30 Hz low-
voltage activity, the beta
rhythm
Known as alpha block,
arousal, or the alerting
response
EEG waves during the
awake state are smaller
in amplitude than those
during sleep – fewer
cortical neurons are
firing in a synchronized
fashion
Polysomnographs and Sleep Stages
Sleep stages are defined by their findings on
polysomnography (PSG)
Stage 1 sleep – transition from wakefulness to sleep
▪ Low-amplitude, low frequency EEG trace known as theta
rhythm (4-7 Hz)
Note – ‘”theta” just refers to
frequency
Theta rhythms can be found
in states of wakefulness
during certain activities as
well
▪ Activity present on the EMG and
EOG – eye movements are slow
and rolling
▪ Known as N1 sleep in more
modern classification systems
Polysomnographs and Sleep Stages
Sleep stages are defined by their findings on
polysomnography (PSG)
Stage 2 sleep – two major EEG features:
▪ K-complexes – high-amplitude spikes that appear
intermittently
▪ Sleep spindles – 7 – 15 Hz
groups of waves
▪ Subject is sleeping lightly and
can be easily awakened
▪ Limited to no eye movement,
activity is present on EMG
▪ Known as N2 sleep in more
modern classification systems K Sleep
complex spindle
Polysomnographs and Sleep Stages
Stage 3 & 4 sleep – EEG waves become less frequent and
larger amplitude
▪ These waves are known as delta waves
▪ Frequency is 0.5 – 4 Hz, and the waves are large in stage
3, and become even larger amplitude in stage 4
▪ Subject is in deep sleep and is
difficult to awaken
▪ Eye movements are minimal –
fluctuations here represent
underlying frontal lobe activity
▪ Together, stage 3 and 4 sleep
are known as N3 sleep
Polysomnographs and Sleep Stages
REM (rapid eye movement) sleep
▪ Unique activity on the PSG:
Bursts of rapid eye movements on the EOG
EMG “flatline” – almost no MSK movement (other
than eye movements)
Low amplitude, higher
frequency EEG which
resembles theta rhythm in N1
– activity is lower amplitude
and not synchronized
▪ Known as R sleep in more modern
classifications
▪ Subjects are easily awakened
from REM, and dreams are
usually recalled upon awakening
Movements during sleep
Electromyograms during N1 – N3 sleep register a number of
movements – often the electrodes are placed on the jaw
and the legs
▪ Eye movements are fairly limited during N sleep, except
for N1, the transition from wakefulness → sleep
▪ N1 – N3 sleep often involves larger movements that
include the axial muscles – i.e. turning over to the other
side, etc.
During REM sleep, descending connections from REM-on
neurons (more later) activate spinal inhibitory neurons that
use GABA as a neurotransmitter
▪ This is why those in REM sleep are effectively paralyzed
– very few movements, other than the odd finger- or
toe-twitch
EEG waves and sleep
The large delta waves seen during N3 sleep are due
to oscillations in activity between the thalamus and
the cortex
▪ The source of the waves in N1 and N2 sleep aren’t as
well known
During REM sleep, the electrical activity occurs in
the cortical association areas and is not
synchronized
▪ Often don’t involve frontal “logic” areas, so this may
offer a simple explanation as to why dreams are bizarre
in nature
Sleep architecture
Sleep architecture refers to
how a person progresses
through each stage of sleep
at night
▪ How long is spent in
each stage
▪ How often and when
each stage is arrived at
▪ How often a patient
awakens
Sleep architecture changes
throughout the lifespan
The first sleep period is the
longest – the rest tend to
last 90 – 110 minutes
Sleep architecture
Healthy young adults and
children usually get most
deep sleep (N3) early, soon
after falling asleep
We usually progress through
the stages in an orderly
sequence, though
sometimes the transition
through N1 and N2 sleep is
very quick
We never go from wakefulness directly to REM (red bar)
▪ We arrive at REM after “ascending” through deeper levels
of sleep, usually N3 but sometimes N2
Sleep architecture
Most REM sleep occurs near
the end of a sleep session
Elderly subjects have much
fewer and shorter periods of
N3 sleep, and more frequent
awakenings
Young children spend a lot
of time in N3 and REM
▪ Almost 50% each in
neonates
▪ steadily declines with
age until ~ 25% each in
young adults
Sleep EEG Other PSG info General Features Lifespan
Stage features

Theta rhythm, 4 Rolling eye Just transitioning into sleep, None notable
-7 Hz movements, easily wakened, may seem
I (N1) some muscle somewhat awake but no short-
activity term memory

Theta with Limited eye Sleep is still light but more With age this
K complexes + movement, some difficult to awaken than N1 stage occupies
II (N2) sleep spindles MSK movement more of the sleep
cycle than N3

Appearance of Limited eye Subject is very difficult to Children – 30 –
III (N3) delta waves, 0.5 movement, some awaken and will be disoriented. 40% of cycle
– 4 Hz MSK movement Sometimes dreams reported. Adults - ~ 25%
More N3 early in the sleep Elderly – very little
Bigger, slower session, less later
IV (N3) delta waves

Dys- Bursts of eye Subject is easy to awaken, and Children - > 25%
synchronized movements, often will report dream content. Adults - ~ 25%
REM theta-like almost no MSK More REM late in the sleep Elderly - < 25%,
(R) movement session, less early on. Need to often very little
be in N2 or N3 prior to entering
REM
 How are sleep-wake states regulated?
In general, there seems
to be an arousal system
(green circles) that keeps
us awake
The arousal system
seems to “open the
gate” of the thalamus
and allow input from
the outside world to
the cortex
The arousal system
also communicates
widely to hypothalamic
areas that regulate
sleep cycles as well as
to the cortex in general
 How are sleep-wake states regulated?
Major components of the
arousal system include
brainstem nuclei that extend
mostly through the midbrain
and pons (lots of green circles)
Locus ceruleus -
norepinephrine
Raphe nucleus - serotonin
Tuberomamillary body-
histamine
Acetylcholine has multiple
nuclei in the brainstem that
are important in arousal
Periaqueductal gray -
dopamine
 How are sleep-wake states regulated?
A nucleus in the
hypothalamus – the
ventrolateral pre-optic
nucleus (VLPO) seems to
be one of the major sleep-
promoting nuclei
▪ Releases inhibitory NTs
like GABA and galanin
REM sleep is likely
regulated differently – in
the brainstem there are
“REM-on” (lateral pontine
areas) and “REM-off”
groups (pons portion of
the locus ceruleus)
 How are sleep-wake states regulated?
The suprachiasmatic nucleus
(SCN):
Communicates with the retina
Is the most likely “site” of our
circadian rhythm
▪ Without light/dark
stimulation, we have a
rhythm that lasts just a little
over 24 hours
Responsible for “entraining” our
circadian rhythm based on light
and dark information
Communicates indirectly with
arousal systems and sleep-
inducing centers
 How are sleep-wake states regulated?
Finally, there are the
“stabilizing” nuclei
The lateral hypothalamus has
a population of neurons that
secrete two major chemicals:
▪ Orexin – projects to both
the arousal systems and to
the VLPO
▪ Melanin-concentrating
hormone (MCH) – also
projects to arousal systems
Orexin and MCH are
important for keeping a
subject in a “stable” sleep
state
A more detailed image - arousal systems
and VLPO projections

Neurobiology of the Sleep-Wake Cycle: Sleep Architecture, Circadian Regulation, and
Regulatory Feedback, Patrick M. Fuller, Joshua J. Gooley, and Clifford B. Saper, Journal
of Biological Rhythms 2006 21:6, 482-493
See notes for details
 Neurophysiology of Sleep
General model:
We don’t want any “halfway
between awake and asleep”
situations
▪ Therefore the sleep centers
will directly and indirectly
inhibit the arousal centers
▪ The arousal centers also
directly inhibit the sleep
centers
There are two drivers that make
us sleepy
▪ The circadian rhythm that tells
us it’s bedtime
▪ The homeostatic signal that
builds the longer we go
without sleep
 Neurophysiology of Sleep
What pushes us towards wakefulness?
Stimuli – whether it’s circadian or homeostatic or some other
stimulus in general – activate our arousal systems
▪ In this diagram they’ve included the tuberomammillary
nucleus (histaminergic), the locus coeruleus (noradrenergic),
and the raphe nuclei (serotonergic)
The arousal system directly inhibits the VLPO nuclei
Orexin activity is increased – and orexin also activates the
arousal nuclei
Orexin + inhibition of the
VLPO → a durable waking
state
 Neurophysiology of Sleep
What pushes us towards sleep?
Stimuli – whether it’s circadian or homeostatic activate the
VLPO
▪ The VLPO directly inhibits both the arousal systems and
orexin release from the lateral hypothalamus
Since orexin release from the lateral hypothalamus is silenced
(orexin stimulates the arousal system) AND increased activity of
the VLPO inhibits the arousal system directly, then a durable
sleep state is maintained
The thalamocortical
oscillations that generate
EEG waves are also turned
back on
A more detailed image - arousal systems
and VLPO projections

Neurobiology of the Sleep-Wake Cycle: Sleep Architecture, Circadian Regulation, and
Regulatory Feedback, Patrick M. Fuller, Joshua J. Gooley, and Clifford B. Saper, Journal
of Biological Rhythms 2006 21:6, 482-493
See notes for details
Neurophysiology of Sleep
Since the sleep-inducing and the arousal groups of neurons
inhibit each other, we’re usually either sleeping or awake,
not in-between
▪ Like a light-switch – this is known as a “flip-flop switch”
▪ MCH release from the lateral hypothalamus
predominates during REM sleep – it inhibits the
monaminergic arousal system (keeps you asleep during
REM)
Neurophysiology of Sleep
This is the case for REM sleep as well
▪ REM-on neurons inhibit the REM-off neurons, and
REM-off neurons inhibit REM-on neurons
▪ REM-on neurons project widely and are stimulated by
cholinergic inputs
cause the previously-mentioned inhibition of
movements as well as the brain activity in the
association areas and limited parts of the
forebrain
▪ REM-off neurons tend to be stimulated by
norepinephrine and serotonin inputs AND they are
also stimulated by orexin release from the lateral
hypothalamus
REM, Non-REM, and Wakefulness model

See description below
A brief segue – melatonin and circadian
rhythms
Melatonin is produced in the pineal gland, a tiny, pea-sized
portion of the epithalamus right above the colliculi in the
midbrain attached to the roof of the 3rd ventricle (no BBB)
▪ It is indirectly
stimulated to produce
melatonin during
periods of darkness
Melatonin is an
interesting metabolite of
serotonin (which a.a.?)
that may have other
functions other than
entrainment of circadian
rhythms
https://upload.wikimedia.org/wikipedia/commons/6/6b/Illu_pituitary_pineal_glands.jpg
 Regulation of melatonin secretion
In the absence of light → retinohypothalamic fibres relay
“dark info” to the SCN → lifting of the inhibition of the PVN
by the SCN
In the absence of light, the PVN then activates the
sympathetic nervous system:
▪ Intermediolateral
horn cells excite
post-ganglionic
neurons in the
superior cervical
ganglion
▪ NE is released at the
pineal gland →
melatonin synthesis
and release
 Regulation of melatonin secretion
Serotonin is synthesized
in the pineal gland
With catecholamine
stimulation (beta1-
receptors) the activity
and production of
AANAT and the
availability of serotonin
increases → more
melatonin synthesized
With withdrawal of
catecholamines, AANAT is
degraded by
proteosomes
What does melatonin do, sleep-wise?
Although the SCN has its own endogenous cycle that is just over
24 hours long, it needs to be entrained
▪ The retinohypothalamic fibres can relay light information and
“synch up” the SCN to day/night periods
▪ However, melatonin also seems to have a role, and activation
of melatonin receptors (most likely MT-2 type receptors are
more important) helps the entrainment of the SCN to light-
dark cycles
Melatonin can both decrease sleep latency and increase the
amount of time that a subject spends sleeping
▪ Thought that MT-1 receptors decrease sleep latency and MT-
2 receptors help maintain sleep for longer (may be
oversimplified)
Melatonin secretion entrains a number of
physiologic/endocrinologic cycles to day-night cycles:
▪ Cortisol secretion and TSH secretion
▪ Core body temperature
▪ Heart rate variability
Melatonin plays a
key role in the
entrainment of
these circadian
rhythms to light-
dark stimuli

https://www.ncbi.nlm.nih.gov/books/NBK550972/#:~:text=The%20main%20function%20o
f%20the,secretion%20of%20the%20hormone%20melatonin.
Homeostatic and Allostatic Regulators
of Sleep
We now are aware of melatonin and the SCN as important
circadian regulators of sleep-wake cycles
However, the longer we go without sleep, the more we
desire it and the more likely we are to lapse into N1 (nod
off) when we close our eyes
▪ This is known as the homeostatic drive for sleep
▪ Although knowledge is still developing, it may be that
extracellular adenosine build-up during wakefulness
may be responsible for the homeostatic drive
Caffeine is an adenosine receptor (A2a) antagonist
A1 receptors are thought to inhibit arousal
pathways, A2a are thought to facilitate sleep-
promoting pathways
Homeostatic and Allostatic Regulators
of Sleep
Allostasis = the response to stressors (physical, psychologic)
that cannot be adequately managed by homeostatic
mechanisms
▪ People who endure psychologic stress have difficulty
sleeping (no surprise there)
▪ The ascending monaminergic arousal system is
excessively activated in these situations
This is of course adaptive if it keeps you from falling asleep
in a stressful situation, but impairs sleep quality over long
periods of time
Common disorders of sleep
Narcolepsy
Restless legs syndrome & periodic limb movement
disorder
Obstructive sleep apnea
Selected parasomnias
Narcolepsy
Thought to affect 1 in 2000 people
▪ Likely underdiagnosed, so could be higher
Characterized by the following features:
▪ Excessive daytime sleepiness
▪ Symptoms that suggest intrusion of REM sleep characteristics
into wakefulness
Cataplexy (in > 50% of sufferers)
Sleep paralysis
Dream-like hallucinations while still awake
Pathogenesis:
▪ 50% of those with narcolepsy & cataplexy have a clear cause
– loss of orexinergic neurons
▪ Pathogenesis is less clear for those without cataplexy
Narcolepsy – Clinical Features
Cataplexy = sudden muscle weakness without a loss of
consciousness
▪ This can be mild – partial weakness of the face or neck
▪ Can be severe – individuals collapse to the ground for minutes,
immobile
▪ Often precipitated by an emotional response to something –
laughing at a good joke, for example
▪ Very diagnostically useful when present – almost no other
disease does this
Excerpt from Harrison’s:
▪ “Many disorders can cause feelings of weakness, but with true
cataplexy patients will describe definite functional weakness
(e.g., slurred speech, dropping a cup, slumping into a chair) that
has consistent emotional triggers such as laughing at a joke,
happy surprise at unexpectedly seeing a friend, or intense
anger.”
Video example: https://accessmedicine-mhmedical-
com.ccnm.idm.oclc.org/MultimediaPlayer.aspx?MultimediaID=20083904
Narcolepsy – Clinical Features
Excessive daytime sleepiness is kind of an understatement
▪ Several times a day, usually after eating or when bored, the
affected person falls asleep – naps usually last 15 minutes
or less, and the person is easily aroused
▪ The napping is pretty much irresistible, and it happens 2 –
6 times/day
▪ Automatic behaviour can occur – patient does routine
tasks, kind of looks awake, but doesn’t respond
appropriately to questions – during attacks
The sleep attacks make driving exceptionally hazardous
Patients who have other sleep disorders can have a similar
presentation, but the napping is usually not as irresistible as in
narcolepsy
Narcolepsy – Clinical Features
Sleep paralysis and hallucinations around the time of falling
asleep (hypnagogic hallucinations) or upon awakening
(hypnopompic hallucinations) are actually common
▪ Occur in 20% of the general population on an occasional
basis
▪ However, usually more frequent in those with narcolepsy
Sleep paralysis occurs on awakening, and is often terrifying
▪ Patients can’t move at all for minutes after awakening,
some feel that they can’t breathe
▪ Outside stimuli (touch or someone walking into a room)
can help terminate the episode
Narcolepsy - Pathogenesis
Easy to see how loss of orexinergic
neurons in the lateral
hypothalamus can lead to almost
every symptom
See poor sleep quality on next slide
Rapid
transitions into
and out of
sleep states
with “blurring
of the borders”
between REM
and
wakefulness
 Narcolepsy – sleep quality
The healthy individual has a long period of NREM sleep before
entering REM sleep
Narcoleptic enters rapid eye movement (REM) sleep quickly at
night and has moderately fragmented sleep
During the day, the healthy subject stays awake from 8:00 A.M.
until midnight
Patient with
narcolepsy dozes
off frequently,
with many
daytime naps that
include REM
sleep
Narcolepsy – Pathogenesis and
Treatment
Why does a patient with narcolepsy lose orexinergic
neurons?
▪ Usually autoimmune - HLA DQB1*06:02 (an MHC II gene) is
found in > 90% of people with narcolepsy with cataplexy
▪ Molecular mimicry of orexin with common respiratory tract
pathogens, including viral influenza and streptococcal species
▪ Narcolepsy with cataplexy is known as Type I narcolepsy
Treatment usually involves antidepressants that increase
noradrenergic or serotonergic tone – these NTs stimulate
REM-off neurons
▪ Methylphenidate or modafinil increase the availability of
dopamine at the synapse – this helps stimulate the “arousal
nuclei” in the brain stem
RLS/PLMD
Restless legs syndrome (RLS) – hard to describe, unpleasant,
irritating compulsion to move the legs that is triggered by rest,
drowsiness, or sleep
▪ Usually interferes with sleep – many report daytime
sleepiness due to interruption of sleep
Makes it difficult to fall asleep – the symptoms only
happen when the subject is awake
▪ Very common – 5 – 10% of adults, more common in women
and in older people
Periodic limb movement disorder (PLMD) occurs during sleep –
movements (often large movements) that frequently involve the
legs
▪ Looks like kicking movements
▪ Very common, often occurs with RLS, and is thought to have a
similar pathogenesis
RLS/PLMD
Pathogenesis is poorly-understood, but knowledge
is developing
▪ Strongly associated with iron deficiency, but most
patients with RLS do not have peripheral signs of iron
deficiency (low ferritin) or anemia
▪ However, studies seem to indicate that deficiency in iron
content in the brain is a common finding in RLS patients
(established through sampling CSF)
▪ Also seems to associated with abnormalities in
dopaminergic signaling – MRI studies suggest that iron
transport is particularly impaired in dopaminergic areas
such as the substantia nigra
RLS/PLMD
Pathogenesis is poorly-understood, but knowledge
is developing cont…
▪ Abnormalities in iron transport/metabolism may impact
a range of dopamine-related processes, including
synthesis (tyrosine hydroxylase) and changes in
dopamine receptors and transporters
▪ Although overall dopamine metabolites are increased in
the CSF, effective treatment involves dopamine agonists
▪ Researchers hypothesize that excessive dopamine
activity in the morning and inadequate dopamine
activity at night may be the cause
RLS/PLMD
Movement disorders are the usual clinical
consequence of issues that impact the basal ganglia
and substantia nigra (extrapyramidal system)
▪ The extrapyramidal system is dependent on
dopaminergic transmission
▪ However, how dopamine neurochemistry is related to
the discomfort of RLS or the movements of PLMD is not
fully understood
▪ The circadian rhythm of dopamine release from
midbrain structures that impact movement (lower at
night) seems to be exaggerated in those that suffer RLS
Obstructive Sleep Apnea
What is it? How is it diagnosed?
▪ Nocturnal findings – 5 or more episodes of obstructive apnea
or hypopnea during one hour of sleep
Apnea = cessation of airflow for ≥ 10 seconds during sleep,
despite respiratory effort
Hypopnea = a ≥ 30% reduction in airflow for at least 10
seconds during sleep that is accompanied oxygen desaturation
or waking
Often those with severe OSA have > 15 episodes/hour
▪ Often the respiratory nocturnal symptoms are accompanied
by gasping, snoring, choking, or waking throughout the night
▪ Nocturnal findings are diagnosed during a sleep study – could
be polysomnography or less complicated methods
Obstructive Sleep Apnea
What is it? How is it diagnosed?
▪ Daytime symptoms
Excessive daytime sleepiness – difficulty maintaining
alertness or involuntary periods of napping
▪ Can actually resemble narcolepsy if sleep deprivation
is severe (but no cataplexy, and less likely to
experience sleep-associated hallucinations or sleep
paralysis)
Reports of an unsatisfying or unrefreshing sleep
Fatigue and morning headaches
Difficulty concentrating, irritability, mood disturbances
May also report dry mouth, heartburn, nocturia, and
diaphoresis in the upper body
 OSA - Pathogenesis
Inspiration results in negative pressures
within the pharynx
▪ We rely on pharyngeal dilator
muscles to keep our upper
pharyngeal airway open
▪ As neuromuscular tone decreases
during sleep, the negative pressure
causes the pharyngeal structures to
collapse
▪ Sites of collapse include:
Soft palate (most common)
Tongue base
Lateral pharyngeal walls and
epiglottis
▪ Unsurprisingly, may be most severe
during REM sleep
OSA - Pathogenesis
Obesity and OSA
Excess adiposity, especially in the upper body (androgenic
distribution) is strongly implicated
▪ Upper airway fat narrows the pharyngeal lumen
▪ Reduces chest wall compliance (the ease of expanding
the chest wall) and can decrease lung volumes
Result is that the lungs/chest wall don’t “pull” the
upper airway structures downwards as well during
inspiration (loss of caudal traction on upper airway
structures)
▪ Estimated that 40 – 60% of OSA cases are due to excess
weight – 10% weight gain is associated with a > 30%
increase in the AHI, a scoring system that ranks
apnea/hypopnea while breathing
OSA - Pathogenesis
Other factors in OSA pathogenesis
Smaller or more collapsible pharyngeal lumen – collapses
more easily during sleep, and requires more neuromuscular
activation to keep patent
▪ Can be narrowed due to enlargement of tongue, palate,
uvula
▪ Can be due to smaller jaws or retrognathia (mandible is
positioned more posterior)
▪ Lower lung volumes outside of obesity exacerbate the
problem (less caudal traction again)
▪ Septal deviation or nasal polyps reduce the pressures
that promote air flow further down in the pharynx
As well, poor nasal airflow → mouth breathing → tongue
falls posteriorly and obstructs the pharynx
 OSA - Pathogenesis
Note the seal that the
tongue makes on the
soft palate with the
mouth closed
▪ When the mouth is
open, the tongue is free
to fall back and seal the
upper airway
▪ Nasal obstruction
therefore complicates
pharyngeal obstruction,
even though the mouth
may be open
OSA - Pathogenesis
Other factors in OSA pathogenesis
Sensitivity to carbon dioxide concentrations in the bloodstream
can also play a role
▪ As carbon dioxide in the bloodstream increases, ventilatory drive
(mostly stimulated by medullary nuclei) also increases
▪ In those without OSA, increases in carbon dioxide concentration
result in appropriate increases in ventilatory drive and stiffening of
upper airway muscles → patent pharynx
If that isn’t enough, then accumulation of carbon dioxide wakes
us up
▪ In those with OSA, a low arousal threshold (hypersensitivity) to
hypercarbia → awakening before increasing pharyngeal stiffness
Can also cause fluctuations in ventilatory drive that result in
periodic airway obstruction and inadequate pharyngeal muscle
activation
▪ As well, a high arousal threshold could result in prolonged apneas -
not waking up even though the airway is obstructed and significant
hypercarbia is occurring
OSA – Risk Factors & Pathogenesis
Already mentioned
▪ variance in jaw size/structure, upper airway structure,
larger tonsils (children with larger tonsils can have OSA)
▪ obesity, variations in ventilatory drive with hypercarbia
Genetics – first degree relatives have double the risk of
having OSA
Male sex – more likely to have upper body obesity, longer
pharynx (easier to collapse)
Age – 5 – 15% prevalence in middle-aged adults, but > 20%
in the elderly
Associated with diabetes, hypertension, and atrial
fibrillation
▪ Chicken or the egg?
 OSA – Diagnostic Considerations
Sleep history should include information from
someone who has observed the patient
sleeping, if possible
Physical and further investigations should
screen for:
▪ Hypertension, cardiac abnormalities (i.e.
signs of CHF or atrial fibrillation)
▪ Oropharyngeal exam should look for
causes of obstruction
Especially nasal polyps, septal
deviation, intra-oral findings as
already discussed
https://en.wikipedia.org/wiki/
FYI – higher Mallampati score (see Mallampati_score
right) increases the risk of OSA
 OSA – Diagnostic Considerations
Gold Standard for OSA diagnosis – polysomnogram
▪ Home sleep tests are economical – they measure nasal air
flow, abdominal/chest excursions during breathing, and
pulse oximetry (at minimum)
High rate of false negatives, and need to be confirmed with
formal PSG
Other testing – FYI
▪ More advanced cardiac testing (looking for atrial
fibrillation, risk of CHF, evaluation of angina if present)
▪ Home BP monitoring
▪ Imaging (CT, MRI) or endoscopy of the upper airway
Parasomnias
Abnormal behaviours or experiences that arise from or
occur during sleep
▪ Sleepwalking (Somnambulism) – automatic motor activities
that occur during sleep
Occur during N3 sleep, so tend to occur early I the evening
Most common in children and adolescents
No clear pathophysiology yet identified
▪ Sleep terrors – usually in young children – child awakens
either screaming or moaning, and exhibits autonomic signs
that indicate fear (also occurs during N3)
Tachycardia, hyperventilation, sweating
After the attack is over, the child does not remember anything
beyond a (mildly) bad dream
▪ For both, often can be avoided by ensuring adequate sleep
Parasomnias
REM sleep behaviour disorder – one of the few
parasomnias that occur during REM sleep
▪ Quite unpleasant – individuals “act out” their dreams and
often results in violent movements (punching, kicking) that
can injure bed partners or the patient
▪ Prevalence increases with age – unfortunately those with
REM sleep behaviour disorder usually develop
neurodegenerative disorders after (i.e. Parkinson’s, Lewy
body dementia)
Seems to predict the development of these later diseases, not
cause them
▪ Thought to be caused by neurodegeneration in the
interneurons that cause paralysis during REM sleep
▪ See here for a video: https://accessmedicine-mhmedical-
com.ccnm.idm.oclc.org/MultimediaPlayer.aspx?MultimediaID
=20083906