Sleep 2 PDF - BMS 200

Summary

This document discusses the role of clock genes in regulating circadian rhythms, sleep, and other bodily functions. It also covers the impact of sleep disruption on various health aspects. The document has information on topics, including metabolic health, hormonal and immune impacts, and other related topics.

Full Transcript

Sleep 2

BMS 200
 Clock Genes?
What is a clock gene?
▪ An intracellular “time-keeping” system present in most (all?) cells that
generate rhythms in biological behaviour
▪ Regulate circadian rhythms, which are the body's natural 24-hour
cycles governing physiological and behavioral processes like sleep-
wake cycles, hormone release, body temperature, and metabolism.
▪ These genes interact through a complex network of feedback loops to
generate and maintain rhythmic activity in cells.
▪ These rhythms are usually approximately 24 hours, but usually need
input from light-dark cycles to stay entrained (synchronized)
▪ These genes are transcribed and produce proteins on an
approximately 24 hour cycle
▪ The following are well-known clock genes:
Clock, Bmal1, the “period” genes (Per1, Per2, Per3), Cry1, and Cry2
▪ The protein products of these genes increase and then decrease over
a 24-hour period – the period is likely synchronized via melatonin
fluctuations
Clock genes in circadian rhythms
Are clock genes responsible for the intrinsic rhythms of
the SCN (hypothalamic nucleus that receives input from
the retina)?
▪ Surprisingly, no – the homeostatic regulation of sleep
is not dependent on clock genes or their products in
the SCN
Are clock genes responsible for intrinsic rhythms in most
of the rest of the body (leukocytes, skeletal muscle,
brain)?
▪ Yes – and these genes seem to be modified by:
Sleep (and sleep deprivation)
Hormones (melatonin and others)
Clock genes in circadian rhythms
How “clinically relevant” are these genes and
their daily fluctuations?
▪ Regulate up to 25% of the human genome
▪ Many of the genes are “metabolic” in nature
Cell growth/division
Energy metabolism, anabolic and catabolic processes
Body temperature
Perhaps various neurological functions – the
hippocampus in particular in association with memory
formation
“Immunologic functions”
Clock Gene Overview - FYI
Clock gene synchronization
Clock genes can be entrained by a variety of stimuli:
▪ Light-dark cycles
▪ Eating
▪ Exercise
Stimuli that can entrain clock genes are called “zeitgebers”
Proper “synchronization” of clock genes seems to promote
normal physiological processes and be somewhat protective
against cardiometabolic disease
▪ People with disrupted sleep cycles are at an increased risk of a
variety of cardiometabolic disorders, as well as a modestly
increased risk of certain types of cancer (epidemiologic evidence)
▪ Many animal studies show that feeding during “active” (i.e.
daylight phases) results in improved insulin sensitivity and
reduced adiposity, even in the face of identical caloric intake
FYI – state of the evidence re: clock
genes
Melatonin
Melatonin is amphipathic – carried by albumin, diffuses readily
across cell membranes
A single daily light pulse of suitable intensity and duration in
constant darkness can phase shift and synchronize the melatonin
rhythm to 24 hours
▪ Higher-frequency (i.e. blue light) is more effective in suppressing melatonin
secretion
Individuals living in dim light are more sensitive to light, and
secrete more melatonin with a smaller “light stimulus”
▪ Blind individuals without light perception show free-running or abnormally
synchronized melatonin and circadian rhythms
Melatonin can act as a paracrine signal within the retina,
Paracrine signaling is a form of cell-to-cell communication in which a cell
releases signaling molecules (like hormones or cytokines) that act on nearby
cells rather than traveling through the bloodstream to distant targets
▪ enhances retinal function in low-intensity light
Melatonin
Increases expression of antioxidant enzymes
▪ superoxide dismutase and glutathione peroxidase
Blocks Bax proapoptotic activity and reduces
caspase 3
Anti-inflammatory and analgesic properties
▪ Inhibits cyclooxygenase (COX) enzyme expression
reducing excessive prostaglandin and leukotriene
production
▪ May have analgesic properties as well via MT1 and
MT2 receptors – reducing pain transmission in
dorsal horn neurons
Melatonin – additional information
Melatonin is a very potent antioxidant, and it seems to be localized
in the mitochondria of a wide variety of tissues
▪ Independent of the receptor effects – the hormone itself has
antioxidant activity
▪ Unsure of the clinical significance of physiological
concentrations of melatonin as an antioxidant – gram per
gram, though, it is a better antioxidant than glutathione
▪ Some evidence that melatonin:
Is protective against breast and prostate cancer
Reduces both systolic and diastolic blood pressure
Has been seen (in rodents) to be neuroprotective in
ischemic stroke model
“Proper” fluctuations in melatonin throughout the day likely
improves overall insulin sensitivity and decreases visceral fat mass
and hyperglycemia
Cardiometabolic consequences of
disrupted sleep - summary
Increased visceral fat mass
Decreased insulin sensitivity and higher
incidence of obesity
Increased incidence of the metabolic syndrome
Dyslipidemia
▪ Lower HDL, elevated triglycerides
FYI – state of the evidence re: sleep disruption in humans
FYI – state of the evidence re: sleep disruption in humans
 Complications of Obstructive Sleep
Apnea (OSA) - Overview
Associated with premature death
▪ Respiratory events lead to increased sympathetic
overactivity ! nocturnal and daytime hypertension
▪ Large intrathoracic negative pressure swings (trying to
inspire against an occluded airway) ! alter preload and
afterload ! cardiac remodeling and reduced function
Increased risk of congestive heart failure as well as
supraventricular and ventricular dysrhythmias
▪ Hypoxia ! vasoconstriction and increased right
ventricular afterload
Formerly thought to be important, however more recent data
indicates that most important cause of increased pulmonary
vascular afterload is congestion due to reduced left ventricular
function
Complications of Obstructive Sleep
Apnea (OSA) - Overview
Associated with premature death
▪ Increased thrombosis and systemic free radical
production likely also contribute to mortality
Atherosclerosis ! Ischemic heart disease and
stroke
Hypercoagulability?
▪ Prevalence of atrial fibrillation and atrial flutter also
higher in OSA
Also contributes to stroke risk
▪ Interestingly, treatment of OSA also improves insulin
resistance
Improved sleep quality?
Sleep Deprivation and
Reproductive Health: Testosterone
Sleep deprivation decreases testosterone
production
▪ Testosterone concentration peaks during sleep
Testosterone declines with age (males 45-74)
▪ Poor sleep quality is associated with lower
testosterone concentrations ! increased in impact
on testosterone levels compared to younger males
Sleep Deprivation and Female
Reproductive System
High levels of melatonin found within ovarian
follicular fluid
▪ Protects oocyte from oxidative stress during
ovulation
▪ Low levels in follicle correlate with increase ROS
and infertility
▪ FYI: IVF outcomes are improved with melatonin
supplementation – increase oocyte quality and
maturation
Sleep: Hormonal and Immune
Impacts
TSH levels increase during sleep
▪ TSH is reduced during chronic sleep deprivation
Cortisol, epinephrine and norepinephrine
decrease during sleep
GH, prolactin increase during sleep
Increased melatonin levels in children help to
suppress GnRH secretion from the pituitary
▪ Decline of melatonin production during adolescence
is linked to onset of puberty
Sleep: Hormonal and Immune
Impacts
Impact of sleep on the immune system
Enhanced production of IL2 and IFN-gamma by T cells during
nocturnal sleep and reduction in IL-10
▪ Nocturnal sleep is associated with shift towards Th1 adaptive
immune response; peaks around 3am
▪ Enhanced antiviral and intracellular bacterial response?
NK cell count and their activity peak in late morning hours
▪ Blocked if experiencing sleep disturbances
IL-6 and TNF (pro-inflam cytokines) increase during the night
▪ IL-6 associated with sleep, while TNF is regulated by other
circadian (non-sleep) factors
Sleep includes increased GH and prolactin release ! increase T
cell proliferation and promote Th1 cytokine activity
Sleep: Hormonal and Immune
Impacts
Summary – Immune:
▪ Impaired sleep may increase the predisposition to
infection
▪ Impaired sleep may decrease the effectiveness of
vaccination (seen in influenza A vaccinations)
▪ Perhaps greater Th1 (vs. Th2) activity during sleep
Sleep and Carcinogenesis
Sleep plays a critical role in various physiological processes, and
its disruption has been associated with an increased risk of
carcinogenesis
This is concerning for those with
Sleep disorders
Shift Workers
Sleep and Carcinogenesis
Shift work: Circadian genes impact expression of genes associated
with cell division and DNA repair
▪ Increased cancer risk in shift workers in epidemiologic studies
(breast, prostate, colon, endometrial and non-Hodgkin’s
lymphoma)
▪ Circadian disruption is deemed “probable carcinogen”
Disorders of sleep:
▪ Increased risk of prostate cancer, but not breast cancer –
associated with problem falling or staying asleep
▪
Circadian Rhythms: Gut
Microbiome
Gut microbiome consists of trillions of
microorganisms residing in the gastrointestinal
tract, plays a significant role in various
physiological processes, even the regulation of
circadian rhythms in the host.
▪ Microbes do not appear to express clock genes
Gut microbiome may be able to regulate the circadian
rhythms of the host
In mice fed a high-fat diet, microbiome-dependent
changes in clock genes (Per2, ARNTL) were seen
within the liver
▪ May be mediated by butyrate production
Circadian Rhythms: Gut
Microbiome FYI
Internal Molecular
Clock:
▪ (1) Central pacemakers
▪ (2) Suprachiasmatic
Nucleus (SCN)
▪ (3) Auxiliary oscillators
Primary clock genes:
▪ CLOCK, ARNTL, PER,
CRY
Secondary clock
genes:
▪ NR1D1, RORA, DBP,
PRARGC1A
Influence other genes
responsible for energy
metabolism and other
functions
Seizures
A seizure is a sudden, uncontrolled electrical
disturbance in the brain that can cause a range
of symptoms,
including changes in behavior, movements,
feelings, and levels of consciousness.
Seizures can vary significantly in their
manifestation, duration, and severity, depending
on the areas of the brain involved.
Seizures
Classifications
▪ Focal seizures – originate from one brain region
Often due to structural problems
▪ Intact or impaired awareness
▪ Motor or nonmotor at onset
▪ Generalized seizures – arise from and spread
rapidly throughout both cerebral hemispheres
Often due to cellular, biochemical or structural
problems
▪ Motor onset – tonic-clonic or another motor
complication at onset of seizure
▪ Nonmotor – absence seizure, sensory, autonomic or
emotional symptoms
Focal Seizures – Intact Awareness
EEG during non-seizure periods of time is typically
normal or exhibiting brief epileptiform spikes or sharp
waves
Arise from: medial temporal lobe or inferior frontal lobe
Presentations and progressions vary:
▪ Seizure may start in one region i.e. motor cortex
responsible for fingers and spread to include entire hand,
patient may experience paresis after the seizures (hours;
rarely days)
May experience sensory changes or emotional
experiences (i.e. déjà vu, fear, detachment)
Focal Seizures – Impaired
Awareness
Impaired awareness
▪ Not necessarily loss of consciousness, but inability
to respond appropriately to environmental changes
(i.e., conversation) and possible having poor
recollection after seizure is done
▪ May experience an aura
▪ May be experience automatism; involuntary,
automatic behaviours
Can be simple like chewing or complex
▪ Full recovery of consciousness may take seconds,
hours or longer
Generalized Seizures 1
Typical Absence Seizures
▪ Sudden, brief lapse of consciousness without loss of
postural control (seconds in duration)
▪ Typical onset during childhood
▪ May occur 100 times per day – appear as
“daydreaming”
Atypical Absence Seizures
▪ Lapse of consciousness is longer and more gradual in
onset
▪ May include focal and motor symptoms
▪ Usually due to diffuse or multifocal structural
abnormalities, which result in additional neurological
complications
Generalized Seizures 2
Generalized, Tonic-Clonic Seizure
▪ Occur in many different clinical setting because can result
from metabolic problems
One of the more common types of seizures
▪ Tonic Phase: Tonic contraction of muscles throughout
body, “ictal cry”, impaired respiration yielding cyanosis,
jaw clenching, increased SNS; lasts 10-20 seconds
▪ Clonic Phase: superimposed periods of muscle
relaxation that increase in duration to a maximum of 1 min
▪ Post-Ictal Phase: unresponsive, muscles are flaccid,
excess salivation (possibly partially obstructing airway),
bladder or bowel incontinence
▪ Gradually regain consciousness after minutes to hours
▪ May complain of headache, fatigue and muscle pain for
hours later
Generalized Seizures 3
Atonic Seizure
▪ Sudden loss of postural muscles 1-2 sec in duration
▪ Brief impairment in consciousness, no post-ictal confusion
Could be as brief as a head drop or a full body collapse
Myoclonic Seizure
▪ Sudden and brief muscle contraction of body part or
whole body
▪ Can be due to metabolic disorders, degenerative CNS
disorders or anoxic brain injury
Epileptic Spasms
▪ Predominantly in infants ! brief flexion or extension of
proximal and truncal muscles
Etiology and Pathophysiology of
Seizures: General
General knowledge/ observations:
▪ Seizure is a shift from normal balance between excitation
and inhibition within CNS
▪ Brain has different seizure thresholds at different
maturational stages
▪ Epileptogenesis – transformation of normal brain tissue
into a network that is hyperexcitable
Include: penetrating head trauma, stroke, infections,
abnormalities in CNS development (congenital)
▪ Epileptogenic factors – specific changes that promote
lowering of seizure threshold
▪ Precipitating factors – trigger or provoke an episode of
seizure (seizures don’t occur 24/7)
Include: psychological or physical stress, sleep deprivation,
hormonal changes, toxic substances, certain meds,
intermittent photic stimulation (video games and strobe lights)
Etiology and Pathophysiology of
Seizures
Almost simultaneous firing of large number of local
excitatory neurons ! hypersynchronization of
excitatory bursts across large cortical region
Individual neuron:
▪ Paroxysmal depolarization shift – long-lasting
depolarization of membrane due to influx of extracellular
Ca2+ ! triggers voltage gated Na+ channels to open !
influx Na+ ! repetitive action potentials
Spike discharge (EEG) – when these action potentials
happen in a relatively synchronized manner in sufficient
number of neurons ! summation of field potentials
Etiology and Pathophysiology of
Seizures
Spread of activation to surrounding neurons is
facilitated by:
1. increase in extracellular K+ which shifts the Nernst
potential for potassium
Resting membrane potential becomes more positive
! neurons reach threshold more easily
2. accumulation of Ca2+ in presynaptic terminals
promoting neurotransmitter release
3. NMDA receptor activation ! additional Ca2+
influx
Etiology and Pathophysiology of
Seizures:
Neonate/ Infant:
▪ Congenital CNS abnormalities, trauma, CNS infection,
hypoxic ischemic encephalopathy, drug withdrawal,
perinatal injury, inborn errors of metabolism (i.e.,
pyridoxine deficiency)
Early Child:
▪ Febrile seizures
Childhood:
▪ Many well-defined epilepsy syndrome present in this age
group, often due to idiopathic or genetic causes
Adolescents and Adults:
▪ Shift towards acquired due to CNS lesions, head trauma,
CNS infection (i.e. neurocystericosis), tumors, illicit drug use
or alcohol withdrawal, autoimmune (i.e., antibodies against
CNS K+ channels)
Etiology and Pathophysiology of
Seizures: Etiologies 2
Older Adults:
▪ Cerebrovascular disease (FYI 50% of new cases of
epilepsy in >65yo), trauma, degenerative diseases
Chronic seizures often appear months or years after
the initial stroke
Any age:
▪ Metabolic disturbances (electrolyte imbalance,
hypoglycemia, hyperglycemia), renal failure, hepatic
failure, hematological disorders, endocrine disorder,
vasculitis as well as variety of medications
Sleep Deprivation and Epilepsy
Sleep deprivation can provoke seizures
▪ Cortical excitability increases with time being spent
awake
▪ This is especially true for generalized epilepsy BUT
not all seizures or epilepsies
Epilepsy can affect sleep quality:
▪ Increase wake time after sleep onset (strongest
feature of epilepsy)
▪ Reduce REM sleep quality and delay the first REM
episode
▪ Change NREM sleep oscillations
▪ Overall disruption of normal sleep
 Taenia – worm infestations
Tapeworm:
▪ Cattle or pigs become
infected by eating
contaminated vegetation
▪ Taenia invades muscle
and survive for years
▪ Humans get infected by
eating undercooked or
raw infected meat (beef,
pork)
▪ SX: mild abdominal
symptoms (attaches to
SI and give rise to
proglottids which exit via
anus and passed in the
stool
Cysticercosis and
Neurocysticercosis
Cysticercosis is infection of the muscle (or other tissue)
by the larval cysts of Taenia solium (pork tape worm)
▪ Worm was able to penetrate the intestinal wall and
disseminate (preference for muscle and brain)
Neurocysticercosis is infection of the brain, which is a
major cause of adult-onset seizures in low-income
countries
▪ Most common parasitic disease of CNS
▪ Complex immune evasion is believed to be the reason it
can survive for so long in the brain without sx
▪ Presentation is variable: minimal sx, then suddenly seizures
and increased intracranial pressure and possibly death
Depends on parasitic load (number of invaders) and location
 Neurocysticercosis Pathogenesis
MMP-9 polymorphism
▪ Associated with patients who exhibit
symptoms (seizures) compared to
asymptomatic, yet infected, patients
▪ Increased BBB permeability (MMP-9
remodels and degrades the BBB) !
thought to allow greater influx of
immune cells into CNS and thus
result in greater inflammatory
response ! degradation of the
cysticerci AND subsequently greater
seizure activity
Trypanosoma brucei and Sleeping
Sickness
Trypanosoma brucei (T.b. gambiense)
▪ Unicellular parasite transmitted by the bite of the tse-tse
fly, extra-cellular parasite
▪ Endemic to sub-Saharan Africa (location of the tse-tse fly)
Sleeping Sickness
3 years in duration; largely fatal (some problematic
treatments exist)
▪ Early phase: parasite is in the bloodstream and interstitial
space of a few organs
Chronic, intermittent fevers, headache, pruritus,
lymphadenopathy, possibly hepatosplenomegaly
▪ Late phase: parasite invades the CNS
Sleep disturbance and neuropsychiatric disorders
Sleeping Sickness
Invade the brain:
▪ Observed in CSF (diagnostic!), but don’t seem to survive
there long, may be penetrating BBB directly (unclear) BUT
there is no damage in BBB itself
▪ Concentrate in the median eminence and hypothalamic
areas
Change in sleep architecture
▪ No change in total amount of time asleep!
Increased daytime sleep and insomnia at night
▪ Similar features with narcolepsy:
SOREM episodes; sudden transition from wake to sleep
Excessive daytime sleepiness
Sleep fragmentation
References
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