ANA (Antinuclear Antibody)

WBC (White Blood Cell Count)

MCV (Mean Corpuscular Volume)

Homocysteine

Basophils (Absolute)

Neutrophils (Absolute)

VLDL Cholesterol (calculated)

Insulin

HS-CRP (High-Sensitivity C-Reactive Protein)

Hematocrit

Bilirubin (Total and Direct)

Alkaline Phosphatase (ALP)

SHBG (Sex Hormone Binding Globulin)

Total Protein

Sodium

Vitamin A (Retinol)

Uric Acid

NRBC (Nucleated Red Blood Cells)

MCHC (Mean Corpuscular Hemoglobin Concentration)

IL-6 (Interleukin-6)

Copper Serum

ApoA/ApoB Ratio

Albumin

Total Cholesterol

LDL Particle Size

A/G Ratio (Albumin/Globulin Ratio)

BUN/Creatinine Ratio

Iron Saturation

EPA (Eicosapentaenoic Acid)

TNF-α (Tumor Necrosis Factor-alpha)

AST (Aspartate Aminotransferase)

Tg Ab (Thyroglobulin Antibodies)

GGT (Gamma-Glutamyl Transferase)

ALT (Alanine Aminotransferase)

HDL Cholesterol

Phosphorous

Hemoglobin A1C

Free Testosterone

Apolipoprotein A1

25(OH)D (25-Hydroxyvitamin D)

Discover the importance of HS-CRP (High-Sensitivity C-Reactive Protein) as a biomarker for longevity and overall health. Learn how it can predict disease risk.

HS-CRP (High-Sensitivity C-Reactive Protein)

HS-CRP is a crucial biomarker used in assessing an individual’s risk for cardiovascular disease and overall longevity. As a high-sensitivity C-reactive protein, it measures low levels of inflammation in the body, which is associated with various age-related diseases. Elevated levels of HS-CRP may indicate a higher risk of heart disease, stroke, and other chronic conditions. By monitoring and managing hs-CRP levels through lifestyle changes and medical interventions, individuals can potentially prolong their lifespan and lower their risk of developing age-related health issues. Utilizing hs-CRP as a biomarker for longevity can provide valuable insights into an individual’s overall health and potential life expectancy.

Biomarker Explained

HS-CRP, or high-sensitivity C-reactive protein, is a crucial biomarker used in assessing an individual’s risk for cardiovascular disease and overall longevity. This biomarker measures low levels of inflammation in the body, which is associated with various age-related diseases. Elevated levels of HS-CRP may indicate a higher risk of heart disease, stroke, and other chronic conditions. When interpreting HS-CRP levels, it is important to consider that lower levels are generally considered better, as they indicate lower levels of inflammation in the body. Monitoring and managing HS-CRP levels through lifestyle changes and medical interventions can potentially prolong an individual’s lifespan and lower their risk of developing age-related health issues. Overall, utilizing HS-CRP as a biomarker for longevity can provide valuable insights into an individual’s overall health and potential life expectancy. By understanding and addressing inflammation levels indicated by HS-CRP, individuals can take proactive steps to improve their health and longevity.

Keywords:

HS-CRP, high-sensitivity C-reactive protein, biomarker, cardiovascular disease, inflammation, longevity, age-related health issues

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How does Rapaymcin work?

Rapamycin slows aging by targeting the mTOR pathway, shifting the body’s focus from growth to repair. It promotes cellular recycling, reduces overgrowth linked to disease, and enhances resilience to stress.

Imagine your body as a city, bustling with activity.

Cells are the workers, and mTOR (mechanistic target of rapamycin) is the city planner, deciding where to focus resources – building new structures, cleaning up waste, or repairing old ones.

As we age, mTOR often prioritizes building (cell growth) over maintenance (cellular repair), leading to “clutter” in our bodies that contributes to aging and disease.

This is where Rapamycin comes in.

It acts like a wise advisor to mTOR, convincing it to slow down unnecessary growth projects and focus on clean up and repair instead.

Specifically, Rapamycin:

Activates cellular recycling (autophagy):

Think of autophagy as the city’s waste management system. Damaged parts of cells are broken down and reused, keeping the system efficient and healthy.

Reduces harmful overgrowth:

Overactive mTOR has been linked to diseases such as cancer, cardiovascular disease, and neurodegenerative conditions like Alzheimer’s. By dialing back excessive growth signals, Rapamycin helps prevent these issues.

Supports stress resilience:

When cells are less focused on growing, they’re better equipped to handle stress, repair damage, and maintain long-term health.