. - Acts as a non-specific transport protein (binds bilirubin, fatty acids, drugs). - Reservoir for thyroid hormone. - Abnormal Levels : Hyperalbuminemia : Elevated levels, often due to dehydration, of little diagnostic value. - Hypoalbuminemia : Low levels are linked to liver disease, increased protein breakdown, malnutrition, malabsorption, renal diseases, and severe burns. Severe hypoalbuminemia (<25g/L) causes edema and hormonal imbalance. 2. Caeruloplasmin - Molecular Weight : 132,000 Da, a major copper-containing protein. - Functions :Transports copper ions. - Acts as an antioxidant. - Clinical Relevance :Key in diagnosing Wilson's Disease , a copper metabolism disorder, where copper accumulates in the liver, kidneys, and brain, and forms Kayser-Fleischer rings in the eyes. - Low levels may indicate malnutrition, liver diseases, nephrotic syndrome, or malabsorption. 3. Transferrin - Molecular Weight : 78,000 Da, involved in iron transport. - Reference Range : 2.2-4.0 g/L. - Function : Transports iron in the blood; levels are regulated by iron concentrations. - Clinical Relevance :Low iron levels increase transferrin production. - Useful for diagnosing anemia , particularly iron-deficiency anemia, where transferrin levels rise. 4. α-Feto-Protein - Molecular Weight : 69,000 Da, a major fetal protein. - Functions : Similar to albumin, involved in immunoregulation during pregnancy. - Clinical Relevance :Used in prenatal screening for neural tube defects (high levels in maternal plasma indicate open neural tube defects). - Low levels may suggest Down Syndrome . - Elevated in liver cancer (about 80% of patients with liver cancer show elevated α-feto-protein). 5. Prostate Specific Antigen (PSA) - Molecular Weight : 33,000 Da, an enzyme found in the prostate. - Reference Range : <4.0 µg/L. - Clinical Relevance :PSA levels above normal suggest prostate cancer , although elevated PSA can also indicate benign prostatic hypertrophy . - Higher PSA levels correlate with an increased likelihood of prostate cancer. 6. C-Reactive Protein (CRP) - Molecular Weight : 105,000 Da, synthesized in the liver. - Function : Part of the acute-phase response to inflammation, aids in bacterial defense and complement activation. - Clinical Relevance :Elevated levels signal inflammation , infection , or autoimmune diseases like rheumatoid arthritis . - Used to monitor infections, autoimmune diseases, and organ transplant rejections. - Normal levels are <8 mg/L, but infections can raise it dramatically (100-fold increase). 7. Tumor Markers - Definition : Specific proteins or enzymes found in the plasma that help diagnose or monitor cancers. - Examples : Acid Phosphatase : Associated with prostate cancer. - Alkaline Phosphatase : Associated with bone and liver cancer. - PSA : Prostate cancer marker. - α-Feto-Protein : Liver cancer marker. - Immunoglobulins : Plasma cell cancers (e.g., multiple myeloma). - Carbohydrate Antigens (CA-125, CA15-3): Associated with ovarian and breast cancers. - Clinical Relevance :Elevated levels can suggest cancer and help monitor disease progression. - Some markers are specific to certain tumors, while others, like enzymes, may be elevated in multiple conditions. - Hormonal Tumor Markers : Tumor secretion of certain hormones can alter protein levels, helping to identify endocrine tumors. 8. Immunoglobulins - Molecular Weight : 150,000-900,000 Da. - Function : Proteins produced by plasma cells that play a key role in immune defense, neutralizing pathogens. - Clinical Relevance :Elevated levels of immunoglobulins can indicate chronic infections or autoimmune diseases . - Immunoglobulin deficiencies are associated with increased susceptibility to infections. Specific proteins serve critical roles in diagnosing a wide range of conditions, from infections and inflammation to cancer and metabolic diseases. The measurement and analysis of these proteins help clinicians in: - Diagnosis : Identifying diseases like cancer, liver, or kidney disorders. - Prognosis : Predicting disease progression and outcomes. - Monitoring : Assessing treatment responses or disease recurrence. By measuring these specific proteins, healthcare providers can obtain crucial insights into a patient’s health status and tailor interventions more effectively. Methods Used in Protein Measurement in Biological Fluids Protein measurement in biological fluids is performed through various methods, each offering different insights into the body’s health: - Chemical Reactions Producing Coloured Products :Example: Burette Method . - Proteins react with chemicals to form colored compounds, which can be measured spectrophotometrically. - Ultraviolet Absorption :Proteins absorb UV light at specific wavelengths (200-225nm, 270-290nm). This method is used to estimate protein concentration. - Precipitation Methods :Proteins are precipitated from the solution using salts or other reagents, and the amount of precipitate is used to quantify the protein. - Dye Binding Methods :Proteins bind to specific dyes (e.g., Coomassie Brilliant Blue), and the intensity of the color change correlates with protein concentration. - Refractometry :Measures the refractive index of the biological fluid, which changes with protein concentration. - Electrophoretic Methods :Proteins are separated based on their charge and size using an electric field. This method allows detailed analysis of protein types in a sample. - Immune-assays :Antibodies are used to detect and quantify specific proteins with high specificity, such as enzyme-linked immunosorbent assays (ELISA). Lipid Profile: Serum Cholesterol, HDL Cholesterol The lipid profile is essential for diagnosing lipid disorders and assessing cardiovascular risk. It includes several key tests and components: - Key Lipid Profile Tests : Total Lipids - Serum Total Cholesterol - Serum HDL Cholesterol (Good Cholesterol) - Cholesterol/HDL Cholesterol Ratio - Serum Triglycerides - Serum Phospholipids - Electrophoretic Fractionation of Lipoproteins :Analyzes lipoproteins like Chylomicrons , LDL , VLDL , and HDL . - Cholesterol :A crucial component found in animal cells, cholesterol serves as a precursor for bile acids, hormones, and other steroids. - Increased Cholesterol Levels :Associated with cardiovascular diseases , atherosclerosis , type II familial hypercholesterolemia , obesity , diabetes , hypothyroidism , etc. - Decreased Cholesterol Levels :Found in liver diseases , hyperthyroidism , anemia , stress , sepsis , etc. Lipoproteins Lipoproteins are proteins bound to lipids, crucial for lipid transport throughout the body. They are classified based on their density and composition: - Chylomicrons :Composed of 1% protein and 99% lipids, with 88% triacylglycerols. - Transport lipids absorbed from the intestines to tissues like adipose and muscle. - Very Low-Density Lipoprotein (VLDL) :Composed of 7-10% proteins and 90-95% lipids (56% triacylglycerol). - Transport triacylglycerols from the liver to tissues needing them for energy or storage. - Low-Density Lipoprotein (LDL) :Composed of 21% protein and 79% lipids (48% cholesterol esters). - Derived from VLDL, LDL transports cholesterol from the liver to peripheral cells. High LDL levels are often linked to atherosclerosis . - High-Density Lipoprotein (HDL) :Consists of multiple subfractions (HDL-1, HDL-2, HDL-3). - Involved in transporting cholesterol from tissues back to the liver for excretion or recycling, contributing to cardio