Is cognitive decline preventable?

Many of the drivers of cognitive decline are modifiable when identified early. Insulin resistance, chronic inflammation, sleep disruption, hormonal decline, elevated homocysteine, and nutrient deficiencies all contribute to cognitive deterioration and all are treatable. The earlier these drivers are identified, the more effectively cognitive trajectory can be modified.

What is type 3 diabetes?

Type 3 diabetes is a term used to describe the relationship between insulin resistance and Alzheimer's disease. The brain is an insulin-dependent organ, and insulin resistance reduces cerebral glucose utilization, producing the metabolic deficit that contributes to neurodegeneration. Patients with type 2 diabetes have 50 to 100 percent increased Alzheimer's risk.

What labs should be checked for cognitive decline?

Comprehensive cognitive evaluation includes fasting insulin and HOMA-IR (metabolic contribution), homocysteine (vascular and methylation), hs-CRP (inflammation), full thyroid panel, vitamin B12 and folate, vitamin D, omega-3 index, cortisol, estradiol or testosterone, ApoE genotype, and heavy metal assessment. Each identifies a specific modifiable driver.

Does sleep affect cognitive decline?

Yes. The glymphatic system, which clears metabolic waste including amyloid-beta from the brain, operates primarily during deep sleep. Chronic sleep disruption impairs this clearance, allowing neurotoxic waste to accumulate. Sleep optimization is one of the most impactful interventions for cognitive preservation.

Can hormones affect brain function?

Yes. Estrogen, testosterone, thyroid hormone, and DHEA all have neuroprotective functions. Estrogen supports hippocampal synaptic plasticity and cerebral blood flow. Testosterone supports spatial memory and cognitive processing. Thyroid hormone governs cerebral metabolic rate. Hormonal decline during aging directly contributes to cognitive deterioration, and optimization can support cognitive preservation.

Home / Conditions / Cognitive Decline Neurological Health

Cognitive Decline

Age-related cognitive decline is not an inevitable consequence of aging it is a consequence of the metabolic, vascular, inflammatory, and hormonal processes that functional medicine identifies and addresses. The brain requires a precise environment to maintain synaptic density, neurogenesis, and neurotransmitter balance. When that environment is disrupted by insulin resistance, chronic inflammation, thyroid dysfunction, vascular impairment, or nutrient insufficiency, cognitive function declines measurably years before a dementia diagnosis is ever considered.

Neurological HealthPreventableMulti-Factor

Decadesthe metabolic and vascular changes driving cognitive decline begin 10-20 years before symptoms

Insulin Resistanceinsulin resistance in the brain is one of the most consistent early drivers of cognitive decline

Modifiablethe majority of cognitive decline risk factors are addressable through functional medicine

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Condition: Cognitive Decline | Category: Neurological and Cognitive Health | Reviewed by: Brian Lamkin, DO

Cognitive decline is not an inevitable consequence of aging. It is the result of modifiable biological processes including insulin resistance, neuroinflammation, mitochondrial dysfunction, sleep deprivation, hormonal deficiency, and gut dysbiosis that accumulate over decades. Identifying and reversing these drivers at the earliest measurable stage produces outcomes that no pharmaceutical intervention after dementia is established can achieve.

What Is Cognitive Decline?

Cognitive decline refers to the progressive deterioration of cognitive function including memory, processing speed, executive function, language, and visuospatial ability that exceeds normal age-related changes. It represents a continuum from subjective cognitive decline (SCD), where patients notice changes not yet measurable on standard testing, through mild cognitive impairment (MCI), where deficits are measurable but functional independence is maintained, to dementia, where deficits impair daily function. The biological processes driving this continuum begin 10-20 years before clinical symptoms emerge, which is when intervention is most effective.

Alzheimer's disease, the most common dementia, is characterized by amyloid plaque accumulation and tau neurofibrillary tangle formation producing progressive neuronal death. The amyloid cascade hypothesis has dominated research for decades but pharmaceutical targeting of amyloid has produced limited clinical benefit, suggesting that amyloid is a downstream marker rather than the primary driver. Emerging evidence supports a metabolic, inflammatory, and vascular model of Alzheimer's pathogenesis in which brain insulin resistance, neuroinflammation, mitochondrial failure, and vascular dysfunction are the upstream causes that amyloid accumulation reflects.

Why It Matters

The Window of Opportunity for Reversal

Alzheimer's pathology begins accumulating 15-20 years before diagnosis; the decade between age 50 and 60 is when metabolic and inflammatory interventions have the greatest capacity to alter the trajectory before neuronal loss becomes irreversible
Subjective cognitive decline and mild cognitive impairment are the reversible stages where comprehensive functional medicine intervention can produce measurable cognitive restoration rather than deceleration of an irreversible process
Brain insulin resistance (type 3 diabetes) is present in the majority of Alzheimer's patients and is largely preventable through lifestyle and metabolic intervention; addressing it before it produces significant neuronal loss fundamentally changes the outcome
The ApoE4 genotype, the strongest genetic risk factor for late-onset Alzheimer's, confers elevated risk but is not destiny; ApoE4 carriers who optimize metabolic health, sleep, and inflammation have substantially better cognitive trajectories than those who do not

Why Conventional Medicine Often Misses It

Cognitive decline evaluation in standard medicine waits until symptoms are functionally significant before investigating; by this point, significant neuronal loss has already occurred
The metabolic, inflammatory, vascular, and mitochondrial drivers of cognitive decline are not systematically evaluated even after diagnosis; the clinical evaluation remains symptom characterization rather than mechanism identification
Sleep evaluation is absent from standard dementia workup despite sleep apnea doubling Alzheimer's risk through impaired glymphatic amyloid clearance and sleep deprivation being the single most modifiable risk factor for cognitive decline
Insulin resistance as the brain energy metabolism deficit is not evaluated in cognitive decline despite being present in the majority of Alzheimer's patients and directly addressable through dietary and metabolic interventions

Common Symptoms

Memory and Learning

Recent memory impairment: difficulty recalling conversations, appointments, and events from the past days to weeks while remote memory remains intact in early stages
Word-finding difficulty (anomia) as one of the earliest and most consistent early cognitive decline markers from hippocampal and temporal lobe vulnerability
Difficulty learning new information and procedures while previously established skills are preserved longer
Getting lost in familiar environments from the spatial memory and navigation impairment that accompanies hippocampal involvement
Repetitive questioning and storytelling from failure to encode new memory formation rather than from deliberate repetition

Executive and Processing

Impaired planning and multi-step task execution from prefrontal cortex and frontal lobe executive function decline
Difficulty managing finances, medications, and complex household tasks from executive function impairment
Slowed processing speed that makes activities requiring rapid information integration more difficult and fatiguing
Impaired judgment and decision-making from the prefrontal-limbic circuit disruption of cognitive decline
Difficulty following complex conversations, reading, or problem-solving from working memory and processing speed impairment

Mood and Behavioral

Apathy and loss of initiative as the most common behavioral symptom of early cognitive decline, frequently misdiagnosed as depression
Irritability and agitation from the loss of prefrontal inhibitory control that normally modulates emotional reactivity
Social withdrawal from the cognitive effort and anxiety that social interactions require when processing becomes difficult
Sleep disturbance from the circadian rhythm disruption that accompanies hippocampal and suprachiasmatic nucleus involvement in cognitive decline
Anxiety and depression as concurrent manifestations of the neuroinflammatory and HPA axis dysregulation driving the cognitive decline

Root Causes: A Functional Medicine Perspective

Brain insulin resistance, termed type 3 diabetes, is the most prevalent and most modifiable metabolic driver of cognitive decline. The brain consumes 20% of the body's glucose and is critically dependent on insulin signaling for neuronal glucose transport, synaptic plasticity, and tau phosphorylation regulation. Brain insulin resistance impairs all three: neurons become energy deficient; synaptic remodeling required for memory formation is impaired; and tau hyperphosphorylation is promoted, directly driving the neurofibrillary tangle formation characteristic of Alzheimer's pathology. Dietary intervention, insulin-sensitizing therapy, and metabolic optimization produce measurable improvements in cognitive function in early decline.

Glymphatic system failure from inadequate sleep is the most clearly preventable contribution to amyloid accumulation. The glymphatic system, the brain's lymphatic waste clearance system, is almost exclusively active during deep sleep. Chronic sleep deprivation or sleep apnea dramatically reduces glymphatic clearance of amyloid beta and tau, allowing accumulation that would otherwise be cleared nightly. Sleep optimization is simultaneously the most impactful and most neglected cognitive protection intervention in standard medicine.

Conventional vs Functional Medicine Approach

Domain	Conventional Medicine	Functional Medicine
Evaluation timing	Evaluation initiated when symptoms are functionally significant; mechanism not investigated	Proactive evaluation of metabolic, inflammatory, vascular, hormonal, and sleep drivers at the first subjective cognitive complaint
Brain metabolic assessment	FDG-PET for glucose metabolism in advanced evaluation; fasting insulin not standard in cognitive decline workup	Fasting insulin and HOMA-IR as standard components; brain insulin resistance identified and addressed as primary metabolic intervention target
Sleep evaluation	Sleep history occasionally taken; sleep apnea evaluation not standard in dementia workup despite doubling Alzheimer's risk	Sleep architecture assessment, sleep apnea screening, and circadian rhythm evaluation as standard components of cognitive decline workup
Inflammatory assessment	hs-CRP not standard in cognitive decline evaluation	hs-CRP, homocysteine, and omega-3 index evaluated; neuroinflammatory burden characterized and reduced through targeted anti-inflammatory intervention
Hormonal evaluation	Not standard; thyroid function occasionally checked; sex hormones essentially never evaluated in cognitive decline	Full thyroid panel, testosterone in men, estradiol in women, DHEA-S, and cortisol evaluated as modifiable cognitive protection factors

Key Labs to Evaluate

Cognitive decline evaluation targets the metabolic, inflammatory, hormonal, and nutritional drivers that are modifiable in the early stages when intervention has the most impact.

Fasting Insulin and HOMA-IRBrain insulin resistance is the central metabolic mechanism of Alzheimer's pathogenesis; the most important modifiable risk factor assessable through standard lab testing

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hs-CRPNeuroinflammation from peripheral inflammatory burden crossing the blood-brain barrier activating microglia and accelerating cognitive decline

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HomocysteineElevated homocysteine directly damages cerebrovascular endothelium and is independently associated with accelerated hippocampal atrophy and cognitive decline

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Free TestosteroneTestosterone supports hippocampal neurogenesis and neuroprotection; its deficiency in men is associated with accelerated cognitive decline and Alzheimer's risk

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IGF-1IGF-1 from growth hormone signaling promotes neurogenesis and BDNF expression; low IGF-1 from sleep disruption predicts cognitive decline severity

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Vitamin D (25-OH)Vitamin D receptors are expressed throughout the brain; deficiency is associated with 2-fold increased Alzheimer's risk and impaired neurotrophic signaling

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How to Interpret These Labs Together

Elevated fasting insulin with elevated homocysteine and elevated hs-CRP identifies the triple metabolic threat to cognitive function. Brain insulin resistance impairs neuronal energy; homocysteine damages cerebrovascular integrity and directly promotes tau phosphorylation; neuroinflammation accelerates microglial activation and amyloid production. This pattern predicts accelerated cognitive decline and responds to concurrent insulin sensitization, methylation support, and anti-inflammatory intervention.

Low free testosterone with low IGF-1 and low vitamin D in a man with early cognitive complaints identifies hormonal and neurotrophic deficiency as primary drivers. Testosterone neuroprotection, IGF-1-mediated neurogenesis, and vitamin D neurotrophic signaling are all impaired simultaneously. This pattern responds to hormone optimization and nutritional repletion more than to pharmaceutical cognitive enhancement.

Elevated hs-CRP with normal metabolic markers but significant sleep apnea history identifies neuroinflammation from glymphatic failure as the primary pathway. Sleep apnea-driven nocturnal hypoxemia and impaired glymphatic clearance are producing amyloid accumulation and neuroinflammation. Sleep apnea treatment is the highest-priority intervention in this pattern; no metabolic or nutritional intervention compensates for ongoing nocturnal amyloid accumulation.

Common Patterns Seen in Patients

The 58-year-old with subjective cognitive decline and insulin resistance of 8 years: word-finding difficulty noticed 2 years ago; fasting insulin of 28 uIU/mL with HOMA-IR of 6.8; brain insulin resistance producing the synaptic energy deficiency impairing memory formation; low-carbohydrate dietary intervention and insulin sensitizing therapy produce measurable cognitive improvement within 6 months; the mechanism that would have been ignored until symptoms worsened significantly
The patient with MCI and severe sleep apnea never treated: AHI of 42 on sleep study performed incidentally; hs-CRP of 4.8 mg/L; nocturnal amyloid accumulation from impaired glymphatic clearance over a decade of untreated apnea; CPAP treatment produces cognitive improvement over 12 months through glymphatic restoration; the most impactful single intervention that had never been offered despite being the most evidence-based one available
The woman with cognitive decline from unidentified hypothyroidism: TSH of 3.8 mIU/L deemed normal; free T3 in the lowest quartile of range; hypothyroidism producing cognitive slowing, memory impairment, and processing speed reduction that was attributed to early Alzheimer's; thyroid optimization produces substantial cognitive improvement within 4 months; a reversible cause of cognitive decline that was never investigated because the TSH was technically normal
The ApoE4 carrier who optimizes metabolic health and maintains cognitive function: heterozygous ApoE4 with family history of early Alzheimer's; comprehensive metabolic intervention at age 52 including low-carbohydrate diet, insulin optimization, omega-3 supplementation, sleep apnea treatment, vitamin D optimization, and resistance training; cognitive testing stable at age 62 while unoptimized ApoE4-positive siblings show measurable cognitive decline; genetic risk modified by modifiable biology

Treatment and Optimization Strategy

Metabolic and Sleep Foundation

Brain insulin resistance reversal through low-carbohydrate or ketogenic dietary approach; ketone bodies provide an alternative neuronal energy substrate that bypasses insulin resistance
Sleep apnea diagnosis and treatment as the highest-priority intervention when present; CPAP therapy restores glymphatic amyloid clearance and reduces the nocturnal hypoxemia-driven neuroinflammation
Fasting protocols: time-restricted eating and intermittent fasting activate autophagy and BDNF production while reducing brain insulin resistance; even a 16-hour overnight fast produces measurable benefit
Aerobic exercise 30-45 minutes daily as the most consistently evidence-based cognitive protection intervention; BDNF release from exercise promotes hippocampal neurogenesis
Resistance training 3 times weekly for IGF-1 production and cerebrovascular blood flow optimization

Nutritional and Hormonal Optimization

Omega-3 fatty acids 2-4g EPA+DHA for neuroinflammation reduction and synaptic membrane fluidity optimization
Homocysteine reduction through methylated folate 1-5mg, methylcobalamin 1-5mg, and B6 for cerebrovascular protection
Testosterone optimization in men with confirmed deficiency; associated with reduced Alzheimer's risk and cognitive protection through hippocampal androgen receptor activation
Vitamin D optimization to 60-80 ng/mL for neurotrophic signaling and neuroinflammation reduction
Lion's mane mushroom extract 500-1000mg twice daily for nerve growth factor (NGF) stimulation and myelin support; among the most evidence-based nutraceutical interventions for cognitive decline

What Most Doctors Miss

Brain insulin resistance is not evaluated despite being the central Alzheimer's mechanism: fasting insulin and HOMA-IR are not standard components of cognitive decline evaluation despite brain insulin resistance being present in the majority of Alzheimer's patients and being directly measurable and addressable through dietary intervention; the 15-20 year window before clinical dementia during which this intervention is most effective is essentially never utilized
Sleep apnea is not evaluated despite doubling Alzheimer's risk: untreated sleep apnea produces nocturnal hypoxemia, impaired glymphatic amyloid clearance, and neuroinflammation that together represent one of the most potent and most preventable Alzheimer's risk factors; sleep evaluation is not standard in cognitive decline workup despite this level of mechanistic and epidemiological evidence
Homocysteine as a cerebrovascular and tau-phosphorylation driver is not measured: elevated homocysteine directly damages cerebrovascular endothelium and promotes tau hyperphosphorylation, the mechanism underlying neurofibrillary tangle formation; it is independently associated with hippocampal atrophy; it is correctable through B-vitamin supplementation; it is not measured in standard cognitive decline evaluation
Hormonal deficiency in cognitive decline is not evaluated: testosterone in men and estrogen in women provide neuroprotection through hippocampal receptor signaling that supports neurogenesis, synaptic plasticity, and amyloid clearance; their deficiency accelerates cognitive decline through measurable biological mechanisms; they are not evaluated in standard cognitive decline workup despite hormonal optimization being one of the most evidence-based neuroprotective interventions available

When to Seek Medical Care

Seek evaluation for cognitive decline at the first consistent subjective complaint of memory, processing speed, or executive function change, even if friends and family have not noticed differences and standard screening tests are normal. Subjective cognitive decline is the earliest identifiable stage where metabolic, inflammatory, and lifestyle interventions have the greatest capacity to alter the trajectory.

Seek prompt evaluation if cognitive symptoms are accompanied by significant sleep disturbance, metabolic syndrome, cardiovascular risk factors, family history of early dementia, or ApoE4 positive status. These concurrent findings substantially increase Alzheimer's risk and represent an urgent indication for comprehensive metabolic and cognitive optimization.

Recommended Testing

Identifying the root cause of this condition requires going beyond standard labs. The following markers provide the most clinically useful insights.

Foundational Labs

Fasting Insulin / HOMA-IR
hs-CRP
Homocysteine
Vitamin D (25-OH)
Free Testosterone (men)

Advanced Assessment

ApoE4 Genotype
IGF-1
Omega-3 Index
DHEA-S
Cortisol (4-point salivary)

Recommended Panel

Metabolic Health PanelComprehensive metabolic assessment characterizing the insulin resistance and inflammatory burden driving brain energy failure and neuroinflammatory cognitive decline.

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Also consider:

Inflammation and Cardiovascular Risk PanelInflammatory and cardiovascular markers including hs-CRP and homocysteine characterizing the neuroinflammatory and cerebrovascular burden accelerating cognitive decline.

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Not sure which testing applies to you?

Explore All Testing Options →

Frequently Asked Questions

Is cognitive decline reversible?

Early-stage cognitive decline, including subjective cognitive decline and mild cognitive impairment, can be meaningfully reversed or substantially slowed when the underlying metabolic, inflammatory, hormonal, and sleep drivers are identified and addressed. Established dementia with significant neuronal loss is not reversible, which is why early intervention is so critical. The 10-20 year window before clinical dementia emerges is when biological intervention produces the most dramatic outcomes.

What is the most important thing to prevent Alzheimer's?

Based on the current evidence, the combination of insulin resistance correction, sleep apnea treatment, aerobic exercise, and homocysteine reduction produces the greatest risk reduction. No single intervention produces more consistent cognitive protection across the evidence base than maintaining insulin sensitivity, which addresses the central metabolic mechanism of Alzheimer's pathogenesis. ApoE4 genotype testing identifies those at highest risk and most in need of early metabolic optimization.

Does diet affect cognitive decline?

Yes, significantly. The Mediterranean diet and its variants reduce Alzheimer's risk by 30-50% in epidemiological studies through mechanisms including reduced neuroinflammation, improved insulin sensitivity, and omega-3-mediated synaptic membrane function. Low-carbohydrate and ketogenic approaches show additional benefit in patients with established insulin resistance by providing ketone bodies as an alternative neuronal energy substrate that bypasses brain insulin resistance.

Does exercise protect against dementia?

Yes. Aerobic exercise is the most consistently evidence-based neuroprotective intervention available without a prescription. It produces BDNF release stimulating hippocampal neurogenesis, reduces neuroinflammation through IL-6 anti-inflammatory pathway activation, improves cerebrovascular blood flow and endothelial function, reduces insulin resistance, and promotes sleep quality. Thirty to 45 minutes of moderate aerobic exercise most days of the week produces measurable hippocampal volume increases on MRI.

What is brain insulin resistance?

Brain insulin resistance, sometimes called type 3 diabetes, refers to impaired insulin signaling within neurons and brain cells. Insulin receptors in the brain regulate neuronal glucose transport, synaptic plasticity, tau phosphorylation, and amyloid clearance. When insulin resistance develops in the brain, neurons become energy deficient, synaptic remodeling is impaired, tau becomes hyperphosphorylated producing neurofibrillary tangles, and amyloid clearance is reduced. This is the central metabolic mechanism of Alzheimer's pathogenesis.

How The Lamkin Clinic Approaches Cognitive Decline

Clinical Perspective

The most important thing I can do for a patient concerned about cognitive decline is evaluate the mechanisms at the earliest possible stage, not wait until the diagnosis is clear and much of the opportunity has passed. Insulin resistance, sleep apnea, homocysteine, and inflammatory burden are measurable today, correctable today, and directly influence whether the trajectory changes. Every year of optimal metabolic health between age 50 and 70 produces measurably better cognitive outcomes at 80. That is what we are building toward. - Brian Lamkin, DO

Brian Lamkin, DO | Founder, The Lamkin Clinic | Edmond, Oklahoma

At The Lamkin Clinic, cognitive decline evaluation begins at the first subjective complaint with fasting insulin, homocysteine, hs-CRP, full thyroid panel, sex hormones, vitamin D, IGF-1, and sleep evaluation. We assess ApoE4 genotype when patients want the full risk picture. Treatment is matched to the identified mechanisms: insulin resistance through dietary and metabolic intervention; sleep apnea through CPAP referral; homocysteine through methylation support; neuroinflammation through anti-inflammatory protocol; hormonal deficiency through targeted optimization. We track cognitive function objectively over time to measure the response.

Related Conditions

Mitochondrial DysfunctionImpaired neuronal energy production as the earliest measurable event in cognitive decline pathophysiology

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Chronic InflammationNeuroinflammation from peripheral and central inflammatory burden crossing the blood-brain barrier and activating microglia

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Insulin ResistanceBrain insulin resistance impairing glucose utilization in hippocampal and prefrontal neurons producing cognitive decline

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Sleep DisturbanceInadequate glymphatic clearance of amyloid and tau from poor sleep accelerating cognitive decline pathology

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Thyroid DysfunctionHypothyroidism producing reversible cognitive impairment that mimics and accelerates early cognitive decline

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Gut DysbiosisGut-brain axis disruption amplifying neuroinflammation and reducing the neurotrophic factor production protecting cognition

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Related Symptoms

Brain FogThe earlier, reversible cognitive impairment that frequently precedes and predicts measurable cognitive decline

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Chronic FatigueNeurological fatigue from mitochondrial dysfunction and neuroinflammation impairing cognitive reserve

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Chronic StressCortisol excess producing hippocampal volume reduction and the memory impairment of chronic stress-driven decline

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Adrenal DysfunctionHPA axis dysregulation reducing the cortisol precision that normally modulates neuroinflammatory set point

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Content authored and clinically reviewed by Brian Lamkin, DO, founder of The Lamkin Clinic in Edmond, Oklahoma. Brian Lamkin, DO has 25+ years of experience in functional and regenerative medicine. This page reflects current functional medicine practice standards and is updated as new clinical evidence becomes available.

Cognitive Decline Is Driven by Modifiable Mechanisms That Can Be Addressed Before Dementia Develops

At The Lamkin Clinic, we evaluate brain insulin resistance, sleep quality, neuroinflammation, homocysteine, and hormonal status at the first cognitive complaint. When we address the mechanisms early, the trajectory changes.

Schedule a Consultation

Medical Disclaimer: This content is provided for educational purposes only and is not intended as a substitute for professional medical advice, diagnosis, or treatment. Lab interpretation should always be performed in clinical context by a qualified healthcare provider. Reference ranges and optimal targets may vary based on individual patient history, clinical presentation, and laboratory methodology. Schedule a consultation to discuss your specific results with Dr. Lamkin.