aging week 3 summary 3 (dragged).pdf

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3.1 aging changes in the neurological system
degeneration of the CNS
neurodegenerative conditions and aging
ex:
- PD
-ALS
- HD
- risk factor: increasing age
primary hallmarks of aging driving neurodegeneration
- genomic instability:
- DNA damage over time
- increased need for DNA repair
- decreased levels of NAD+ and sirtuins
telomere attrition
- shortening of telomeres w age
- impact on cellular aging
epigenetic alterations
- changes in gene expression regulation
loss of proteostasis
- decline in protein quality control
- accumulation of misfolded proteins
mechanisms and effects
DNA damage and repair
- ongoing DNA damage leads to cellular synthesis
- increased overall inflammation
mitochondrial dysfxn
- contributes to decreased central nervous system function
inflammation
- accelerates the aging process

- interaction of genomic instability, telomere attrition, epigenetic changes, and proteostasis loss
leads to neurodegeneration
- aging as a significant risk factor for neurological diseases thru these mechanisms

changes in brain structure
ventral dilation and neuron changes
ventral Dilation
- some degree is expected w aging
cortical neurons
- shrinkage occurs
- # remains relatively the same
cortical atrophy
affected areas:
- frontal cortex
- temporal cortex
- prefrontal cortex
- potentially the hippocampus (memory capacity)
minimal atrophy:
- subcortical nuclei, except possibly the substantia nigra
- impact on dopamine use by the strata
brain wt and size
- atrophy effect:
- decrease in brain wt w age
variability:
- normal variability in brain sizes among individuals
 normal aging involves specific patterns of atrophy and neuron shrinkage
significant areas include the frontal and temporal cortices, and potentially the hippocampus, w
minimal impact on subcortical nuclei except the substantia nigra

physiologic changes to vasculature in the CNS
arterial wall changes
loss of elasticity:
- increased likelihood of atherosclerosis (not considered normal aging)
tortuosity:
- vessels become more tortuous or windy
- slower perfusion of brain tissue
BBB Changes
- decreased protectiveness:
- decreased waste elimination
- impaired reactivity in brain vasculature to meet demands
neural processing efficiency
reduced efficiency:
- decreased myelin
- decreased vasodilation capacity
changes in the brain's vascular system contribute to reduced neural processing efficiency
includes loss of arterial elasticity, increased vessel tortuosity, decreased blood-brain barrier
protectiveness, and impaired waste elimination and vasculature reactivity

impact on cognition
seattle longitudinal study findings
overall cognition:
- linear age-related declines observed
areas of rapid decline:
- processing speed
- episodic memory
- spatial ability
- reasoning
minimal change:
- numeric ability
- verbal ability
cognitive decline and mortality
related studies:
- plotted mortality based on cognitive decline
acceleration of cognitive decline:
- begins approximately 3-6 years before death
significant cognitive declines in certain areas w aging
acceleration of cognitive decline near end of life

impact of cognition fxn

memory and processing speed
short term memory:
- modest decline
processing speed:
- continued decline throughout
adulthood
verbal intelligence and personality
verbal intelligence:
- stable until the 60s
personality:
- no substantial changes
sleep patterns
variability:
- more variable sleep patterns and duration
frequent awakenings and naps:
- increased frequency
challenges w normal aging
info processing:
- decreased fluidity and speed impacting intelligence
attention:
- decreased stability to divide attention
executive tasks:
- challenges w new tasks
learning and recall:
- decreased learning and recall of new info
word finding:
- challenges w spontaneous word finding
mental flexibility and reaction time:
- decreased mental flexibility
- increased reaction time
maintained fxns
independence w general fxns:
- attention span
- real world executive fxn
- comprehension and vocabulary
- long-term procedural memory
aging involves specific cognitive and functional changes while maintaining certain abilities and
independence in general fxns

reversible changes
focus: evidence supporting reversibility of cognitive decline with physical activity and nutrition
accelerated changes and cognitive impairment
- early onset:
- accelerated changes leading to mild cognitive impairment (MCI) or dementia
impact of physical activity
- mitigation and reversal:
- role of physical activity in reducing and possibly reversing biological hallmarks of aging
role of nutrition
- mitigating effects:
- contribution of nutrition to combating aging-related cognitive decline
future directions
- research trends
- further investigation into mechanisms of reversibility
- integration of physical activity and nutrition in cognitive health strategies
both physical activity and nutrition demonstrate potential to mitigate and reverse buildup of
aging biological hallmarks associated with cognitive decline
continued research is crucial to fully understand and optimize these interventions
in the peripheral nervous system
brain fxn
processing and reaction time:
- decreased w age
- impact on overall cognitive fxn
peripheral nervous system
- impact on sgnaling feedback:
- quality and quantity affected by decreased fxn
structural changes in the PNS
myelin sheath health:
- decreased due to impaired remyelination by oligodendrocytes
nerve conduction velocity:
- slowed due to reduced myelin integrity
other impacts on PNS
endoneurial blood flow:
- decreased
nerve regeneration and repair capacity:
- impaired
- protein transport:
- affected
microglia and astrocytes fxn:
- impaired fxn
neuromuscular jxn changes
structural alterations:
- impact on nerve signaling
aging affects both central and PNS fxn
decreased processing and reaction time influences somatosensory, visual, and vestibular signaling
structural changes in the PNS contribute to reduced nerve conduction velocity, impaired
regeneration, and altered neuromuscular junction signaling

impact on PNS fxn
vision
depth perception and visual acuity:
- difficulty due to decreased lens elasticity
- impacts on accurate depth perception
hearing
- upward gaze and high-frequency sounds:
- limitation of upward gaze
- loss of acuity for high-frequency sounds
somatosensory and spinal reflexes
general changes:
- altered processing in somatosensory perception
- changes in spinal reflex responses
gait and posture
age-related changes:
- normal alterations in gait and posture
- not typically leading to false perceptions or balance issues
aging affects sensorineural processes across vision, hearing, somatosensory
perception, spinal reflexes, gait, and posture
important to note changes in depth perception, visual acuity, upward gaze,
high-frequency sound perception, and normal gait and posture alterations
impact on vision
cataracts
- blurry vision due to protein buildup on the lens
- no change in field of vision
impact:
- overall vision becomes progressively blurry
glaucoma
- optic nerve damage caused by elevated intraocular pressure
- leads to tunnel vision
impact:
- gradual loss of peripheral vision
macular degeneration
- degeneration of the macula, central part of the retina
- decreased central vision
impact
- increased reliance on peripheral vision

-cataracts: blurry vision without peripheral vision loss
-glaucoma: tunnel vision due to peripheral field loss
-macular degeneration: central vision loss, increased dependence on peripheral vision
these conditions represent abnormal changes in vision with age, necessitating medical
attention

Summary
Known changes in nervous system function and structure occur with
age, but are reversible

this bish..stays doing the most. this shouldnt be 5 pages
 3.2 impact of exercise on aging neurological system
physiological impact in the CNS
intro to exercise and metabolic switching
- exercise induces intermittent metabolic switching
- body's response to demands leads to metabolic rate changes
effects on ketones and synaptic activity
- increased buildup of ketones
- enhanced synaptic activity
impact on trophic factors
- brain derived neurotrophic factor (BDNF)
- fibroblast growth factor 2 (FGF-2)
- vascular endothelial growth factor (VEGF)
activation of signaling pathways
- concurrent activation of pathways
- Induction of transcription factors
enhancement of neuroplasticity and resilience
- genes encoding proteins for neuroplasticity
- resilience during aging
overall effect on physiological aging
- minimization of maladaptations
- promotion of healthy aging processes

impact on cerebral blood flow
impact of exercise on brain
- increased cerebral blood flow and basal reactivity
- decreased brain atrophy over time
cognitive fxn improvement
- neuroprotection effects
- increased cerebral vascular and cognitive reserve
specific effects on aging
- normal aging effects on blood flow.
- decreased flow in frontal and parietal lobes.
- increased flow in cingulate and insular regions
- contrasting effects in pathologies like mild cognitive impairment or dementia
comparison of active vs. sedentary lifestyles
- differences in blood flow patterns
study ex
- impact of 12 wks of aerobic exercise
- reversal of blood flow discrepancy towards left insula
- improved working memory and verbal fluency demonstrated by participants

neuroprotective effects

neuroprotective effects of exercise on endothelial fxn
- exercise enhances endothelial function in the central
nervous system
- increased production of growth factors:
- peripherally produced growth factors entering systemic
circulation
- brain-produced factors
improvements in neurotransmitter modulation
- enhanced synaptic function and plasticity
- improved energy metabolism
- promotion of neurogenesis and cell survival
additional impact on cognitive
focus on executive function, memory, and neuroplasticity
- emphasis on brain's executive fxn and memory
- + effects of exercise on neuroplasticity
additional effects of physical activity
- cascade of effects on hormone levels:
- serotonin.
- melatonin.
- dopamine.
- impact on mood regulation.
- decrease in depressive sx’s demonstrated in multiple studies.

impact on brain structure

impact on brain structure
study by erikson et al. (2010)
- randomized controlled study.
- participants: 120 pts w/o dementia.
- intervention groups:
- aerobic exercise 3x a wk at mod intensities
- stretching group
results:
- aerobic group: 1.97 to 2.12% increase in hippocampal
volume
- stretching group: 1.4% loss in hippocampal volume
conclusion: aerobic exercise can reverse 1 to 2% annual
hippocampal volume loss attributed to age in healthy adults
supporting studies
- other studies on progressive resistance training
- similar positive results observed
overall benefit
- promotion of both exercise interventions shown to be
beneficial

impact at the neuromuscular jxn
impact on the peripheral nervous system
- focus on the neuromuscular junction.
- changes during normal aging:
- more mitochondria, deeper postsynaptic junctions, densely located acetylcholine
receptors.
- aging effects: fewer mitochondria, shallower junctions, fewer activated receptors.
effects of physical activity
- induces:
- increased mitochondrial genesis.
- improved mitochondrial function and ATP availability.
- increased pre- and post-synaptic activity.
- increased # of receptors.

summary
 3.3 path cognitive changes
pathological aging for the CNS
: 3 Ds
focus on:
- depression
- delirium
- dementia
spectrum of dementia
- early changes identified as mild cognitive impairment (MCI).
- progression towards cognitive diseases possible continued accelerated aging processes.
mild cognitive impairment (MCI)
- precursor to dementia.
- can be:
- arrested.
- reversed in some individuals presenting MCI.

course of cognitive changes w age
cognition in older adults
normal changes
- modest decline in short-term memory.
- continued decline in processing speed.
- verbal intelligence and personality remain stable.
impact of accelerated aging
- rapid and steep decline towards mild cognitive impairment (MCI) or
cognitive disease.
improving cognitive fitness
strategies:
- physical activity.
- nutrition.
- engagement in cognitive activities.
benefits of cognitive fitness
- increases cognitive reserve.
- maintains fxn and health.
diagnosis of mild cognitive impairment (MCI)
- signifies significant loss in cognitive fitness.
- potential swift progression to cognitive disease.

mild cognitive impairment

Definition: “a transitional zone between normal aging and dementia” and is a “symptomatic
predementia range of cognition
and function... and is not normal” Jekel K et al., 2015 & Albert MS et al., 2011
60 yrs: prevalence is low
^ 1 to 6.7 %
rates increases w age to about 25% by age 85
contributors to mild cognitive impairment
causes of mild cognitive impairment (MCI)
- no single cause; multiple variables involved
contributors:
- health status
- socioeconomic determinants of health
- gender or genetic predisposition
negative contributors
- HTN or vascular pathology
- brain infarction
- altered lipid metabolism
- environment
- medication
- illness
- trauma
mitigators
- higher level of education
- antidepressant therapies
- statins
DSM-5 diagnostic criteria mild neurocognitive disorder
- moderate alcohol consumption
practice guideline for MCI
- cholinergic therapies
- anti-inflammatory agents diagnostic criteria for mild cognitive impairment
impact of lifestyle (MCI) by Albert et al.
altered by: - concern regarding a change in cognition.
- diet - impairment in one or more cognitive domains:
- physical activity - memory
- executive fxn
more practice guidelines for MCI - attention
practice guidelines by Peterson et al. - language
aim: guidelines for mild cognitive - visual spatial skills
impairment (MCI). - preservation of independence in functional
recommendation: weaning from abilities (e.g., paying bills, preparing meals).
medications contributing to cognitive dx:
impairment if possible. - excludes presence of dementia.
pharmacological tx types of mild cognitive impairment
status: amnestic:
- no approved pharmacological tx for - involves memory loss.
MCI. non-amnestic:
- none shown effective for - primarily involves attention.
prevention. clock drawing test
benefits of exercise - comparison across stages:
types of exercise: - healthy adult
- aerobic. - mild cognitive impairment (MCI).
- strength training. - late alzheimer's disease.
- combined training. observations:
studies' findings: in MCI:
- prevents declines in cognitive fxn - general structure of the clock present.
in individuals w normal fxn - altered spacing of numbers.
exercise recommendations for MCI - imprecise or inaccurate hands.
frequency:
- at least two times a week.
duration:
- at least 6 months.
goal:
- prevent further decline towards
dementia.
effect on training on MCI
meta-analysis by Meng et al., 2022
aim: impact of interventions on preventing progression of mild cognitive impairment (MCI)
types of Interventions studied
- cognitive training
- physical therapy
- physical activity alone
- no training (control group)
findings
- combined cognitive and physical training:
- + effects on global cognition compared to control group
- +effects on memory compared to physical activity alone or control
- + effects on executive fxn compared to all other groups
definition of cognitive training
mental exercises to improve cognition:
- memory
- executive fxn
- processing speed.
- visual spatial perception
also known as:
- brain games.
- cogniSize.
- neurobics.

which training?
PT and mitigating mild cognitive impairment (MCI) progression
- importance of physical activity in managing MCI progression.
optimal exercise types
systematic review by Huang et al., 2022
-examined efficacy of exercise interventions on cognitive fxn
findings:
- resistance exercise:
- highest probability to slow cognitive decline
- particularly beneficial for those with cognitive dysfxn (e.g., dementia)
multi-component exercise:
- most promising for neuroprotective effects
- effective in preventing global cognitive loss and enhancing executive fxn in MCI
- combo of any 2 types of exercise:
- resistance training
- balance training
- aerobic training
impact on memory
resistance training:
- higher impact on memory in MCI
effectiveness of mind-body exercises
- tai Chi, yoga, dance:
- not shown to be more beneficial overall compared to multi-component or resistance
training
progression of MCI
impact of physical activity
- potential to reverse or halt progression of mild cognitive impairment (MCI)
progression of mild cognitive impairment (MCI)
- some cases progress to dementia.
statistics on progression
- 10%-15% of individuals with MCI progress to alzheimer's disease or other dementia per year
- 55%-65% eventually progress to some form of dementia
types of MCI
- amnestic MCI variant:
- progresses to dementia at a ratio of 3 to one compared to other variants

Summary
Mild cognitive impairment presents with decreased cognitive function with intact
functional independence
Exercise alone has significant impact on slowing cognitive decline
 3.4 into to dementia
DSM-5 diagnostic criteria: major neurocognitive disorder
diagnostic criteria for dementia
memory impairment:
- difficulty learning new info or recalling previously learned info
presence of one or more of:
- aphasia (language impairment).
- apraxia (inability to execute motor activities).
- agnosia (failure to recognize or identify objects despite intact sensory fxn).
- disturbance in executive fxn (e.g., planning, organizing).
fxn impairment
- significant decline in social or occupational fxning
delirium and dementia
relationship:
- not exclusive; can occur concurrently.
- overlap can lead to misdx or lack of dx.

types of dementia
dementia overview
- umbrella term for sxs related to cognitive impairment
major types of dementia
alzheimer's disease:
- most common cause
vascular Dementia:
- second most common
lewy body dementia
- frontotemporal dementia
less common types
- prion diseases (e.g., Creutzfeldt-Jakob disease).
- neurodegenerative diseases associated w:
- parkinson's
- chronic traumatic encephalopathy (CTE)

vascular dementia
definition and epidemiology
- second most common type of dementia.
- associated w vascular comorbidities:
- HTN
- atrial fibrillation.
- stroke.
- diabetes.
- smoking.
clinical presentation
distinguishing features from alzheimer's disease
- abrupt and stepwise symptom onset
- often associated w minor strokes or small vessel disease
- cumulative cognitive decline over time.
 affected fxns
- memory.
- abstract thinking.
- judgment.
- attention.
- complex activities.
variable fxnal deterioration
- selective based on affected vasculature
behavioral changes
- altered impulse control
- change in personality
- emotional ability
- depression
- apathy

vascular dementia: imaging
vascular dementia characteristics
- affected brain regions
- more common in frontal lobes than temporal lobes
cognitive performance compared to alzheimer's disease
- poorer performance in:
- verbal fluency
- perseveration
- abstract thinking
better recall and memory compared to Alzheimer's disease
neuroimaging findings
- MRI:
- detects lacunar infarcts due to chronic reduced blood flow
- PET scan interpretation:
- red indicates more active areas.
- green indicates less active areas.
comparison with Alzheimer's Disease on neuroimaging
- alzheimer's disease:
- increased frontal lobe activity (red).
- decreased parietal and temporal lobe activity (green).
vascular dementia:
- multiple white areas on MRI (indicating lacunar infarcts).
- increased parietal and temporal lobe activity (PET scan).
- decreased frontal lobe activity (PET scan).

vascular dementia: pathophysiology

pathogenesis of vascular dementia
differentiation from other dementias
- related to stroke pathogenesis
- combination of modifiable and non-modifiable risk factors

& sex race an genetics
age , ,
stroke mechanism
- thrombotic or embolic stroke.
- blocked blood supply to brain region.
- leads to hypoperfusion.
cascade of effects
- oxidative stress.
- endothelial dysfxn
- neuronal dysfxn
- vascular cognitive impairment
modifiable risk factors
- importance in reducing stroke risk:
- smoking cessation
- diet management
- physical activity
management of comorbidities
aimed at preventing:
- HTN
- diabetes
- hyperlipidemia

lewy body dementia
lewy body dementia (LBD) overview
association with parkinsonism
- commonly diagnosed alongside PD
pathophysiology
- cause:
- buildup of alpha-synuclein protein (Lewy bodies) inside neuron nuclei
result:
- neuronal degeneration in cortex or brainstem.
genetic links
- associated genes:
- PARK11
- full life of protein genes
distribution of alpha-synuclein
- throughout the brain
- accumulation in basal ganglia:
- leads to dopamine degradation
- contributes to neuronal death
clinical ex
robin williams:
- initially diagnosed with PD
- later found to have Lewy body dementia (LBD).
- tragic outcome: suicide.

lewy body dementia clinical presentation
motor sx’s of lewy body dementia (LBD)
- decreased effective use of dopamine in basal ganglia
- parkinsonian motor sx’s:
- stiffness
- tremor
- poor coordination
- difficulty walking
non-motor sx’s of LBD
distribution of lewy bodies
- accumulation throughout the brain