1 / 46

CHO METABOLISM BY Dr. Naglaa Ibrahim Azab Assistant professor of medical biochemistry

CHO METABOLISM BY Dr. Naglaa Ibrahim Azab Assistant professor of medical biochemistry. BLOOD GLUCOSE HOMEOSTASIS (Regulation of blood glucose level). What is glucose homeostasis???. It is the maintenance of blood glucose level within the normal range .

mercury
Télécharger la présentation

CHO METABOLISM BY Dr. Naglaa Ibrahim Azab Assistant professor of medical biochemistry

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CHO METABOLISM BY Dr. Naglaa Ibrahim Azab Assistant professor of medical biochemistry

  2. BLOOD GLUCOSE HOMEOSTASIS(Regulation of blood glucose level)

  3. What is glucose homeostasis??? It is the maintenance of blood glucose level within the normal range

  4. Normal blood glucose level (mg/dl) Fasting (6-12 h after meals) 70-110(126) 130-150 1 h after CHO meals 2 h after CHO meals 70-110(126) Starvation (prolonged fasting) 60-70

  5. Importance of glucose homeostasis Maintain a continuous supply of sufficient blood glucose to the brain and CNS Sudden hypoglycemia (< 40 mg/dl) lead to???? Coma and even death

  6. Glycogenolysis (Liver glycogen) Gluconeogenesis (mainly from amino acids) Diet by digestion and absorption Main source during prolonged starvation (> 18 hrs) Source during early fasting (12- 18 hrs) mostly Blood glucose Uptake by Tissues as muscles, adipose tissue & brain Oxidation glycogenesis lipogenesis

  7. How to maintain the balance between addition and removal of glucose??? • (What are the factors important for maintaining glucose homeostasis • What are the factors that regulate blood glucose level???? tissues hormones

  8. Tissues regulating blood glucose level Muscles and adipose tissues GIT Liver Kidney

  9. GIT Maximum rate of glucose absorption is 1 gm glucose/Kg body weight / hour → prevents sudden hyperglycemia after meal. Glucose \/ \ ↑intestinal factors ↑ enterogastrone hormone from duodenum \ \ • stimulate insulin secretion from pancreas • - - - gastric evacuation

  10. Liver (Blood glucostat) After CHO diet Fasting Uptake \ Glycogenolysis \ \ Oxidation Glucose \ \ \ Glycogenesis Gluconeogenesis LIPOGENESIS Blood glucose Blood glucose

  11. Muscle &Adipose tissue After CHO diet Fasting Uptake \ Gluconeogenesis Muscle:Release alanine to liver Adipose tissue:by lipolysis release glycerol and f.as \ Oxidation Glucose \ \ \ Glycogenesis in muscle Lipogenesis In adipose tissue Blood glucose Blood glucose

  12. Kidneys Renal threshold for glucose is 180 mg/dl

  13. Hormones

  14. Insulin Uptake (except brain, liver,RBCs- non dependant) \ \ Glycogenolysis \ \ \ Oxidation Glucose \ \ \ Glycogenesis Gluconeogenesis \ LIPOGENESIS Lipolysis Blood glucose

  15. Glucagon and adrenaline Uptake \ Glycogenolysis \ \ \ \ Oxidation Glucose \ \ \ Glycogenesis Gluconeogenesis \ LIPOGENESIS Lipolysis Blood glucose

  16. Clucocorticoids and G.H. Uptake \ \ \ Glucose Gluconeogenesis \ \ Oxidation \ \ a.as ( glucocorticoids) Lipolysis ( G.H) Blood glucose

  17. Thyroid hormones Uptake Absorption \ \ \ \ \ \ Glycogenolysis Oxidation Glucose \ \ \ Glycogenesis Gluconeogenesis LIPOGENESIS Blood glucose

  18. Glucosuria

  19. Presence of detectable amounts of glucose in urine (> 0.5 g/day, normally < 150 mg/day).

  20. Causes: I. Hyperglycemic glucosuria: 1) Diabetes mellitus glucosuria 2) Adrenaline glucosuria - Pheochromocytoma. - Emotions. - Stress (oral examination). - Hypotension - Injection 3) Alimentary glucosuria: It is due to intake of large amounts of glucose after prolonged carbohydrate deprivation.

  21. Causes: II. Renal glucosuria (plasma glucose < 180 mg/dl): 1) Congenital glucosuria : = renal diabetes = Diabetes innocence = benign glucosuria. 2) Pregnancy glucosuria : Occurs in about 20% of normal pregnancies. 3) Nephritis & Nephrosis : Only some cases show glucosuria. 4) PhlorrhizinGlucosuria : Phlorrhizin inhibits renal tubular reabsorption of glucose.

  22. Diabetes mellitus

  23. DM hyperglycemia \ \ \ \ glucosuria syndrome \ \ polyuria \ \ \ polydepsia polyphagia Loss of weight

  24. Causes ↓insulin level or insulin resistance ↑anti-insulin hormones (glucagon, adrenalin ) Types Type I: Insulin dependent DM =IDDM = Juvenile diabetes. Type II: Non Insulin dependent DM =NIDDM = Maturity onset DM

  25. Metabolic changes in DM 1-Disturbed Carbohydrates metabolism: hyperglycemia due to - Decreased glucose uptake and utilization by tissues. - Decreased glycogenesis &lipogenesis. - Increased glycogenolysis &gluconeogenesis. 2-Disturbed lipid metabolism: hyperlipidemia and hypercholesterolemia due to - Increased lipolysis and plasma FFA - Increased ketogenesis: which may cause ketoacidosis

  26. Metabolic changes in DM 3-Disturbed protein metabolism: Negative nitrogen balance ,wasting ,weakness of muscle and delayed healing of wounds due to - Decreased protein anabolism. - Increased protein catabolism. • 4-Disturbed water and electrolyte balance: • Glucosuria→ osmotic dieresis → polyuria → dehydration → polydepsia • Increased loss of Na+ & K + in urine.

  27. Complications of DM • 1-Macrovascular complications of DM: • (atherosclerosis, hypertension, myocardial infarction and renal failure). • Most of these complications are due to damage of the large blood vessels by glycosylation of protein molecules in the wall of blood vessels secondary to hyperglycemia. • The presence of hypercholesterolemia and hyperlipoproteinemia increase the risk for the development of atherosclerosis and its complications. 2- Microvascular complications: They affect the small blood capillaries and lead to : Diabetic retinopathy and neuropathy . These are due to vascular damage caused by protein glycation and sorbitol (the alcohol of glucose ) accumulation.

  28. Complications of DM 3- Diabetic cataract : It usually occurs in young age . It is due to accumulation of sorbitol in the eye lens, which leads to osmotic accumulation of fluid in the lens lead to its opacity. 4-Diabetic coma: Coma is loss of consciousness. There are many types of coma.

  29. Differences between hyperglycemic and hypoglycemic coma

  30. Treatment of coma • hyperglycemic coma treated by • insulin and glucose intravenous to avoid sever drop of blood glucose • correction of electrolyte imbalance resulting from acidosis and polyuria . • hypoglycemic coma treated by • glucose infusion.

  31. Diagnosis of DM 1- By measuring the blood glucose level in fasting( 8-12 h) state and two-hour postprandial blood glucose level. a) Normally: Fasting blood sugar = 70 – 110 mg/dl. 2-hours postprandial = up to 140 mg/dl. b) In Diabetics: Fasting blood glucose = > 140 mg/dl. 2-hours postprandial = > 200 mg/dl.

  32. Diagnosis of DM • 2- Oral glucose tolerance test (OGTT): • After fasting 8-12 hours, the patient is given 70 gm D-glucose (1 g/Kg body weight) in a cup of water • Blood and urine samples are taken fasting, ½, 1, 1½, 2, 2½ hours. • - Samples are analyzed for glucose. • - A blood sugar curve is plotted.

  33. Diagnosis of DM

  34. Diagnosis of DM Comments on normal & abnormal oral glucose tolerance curves

  35. Diagnosis of DM • In normal persons: • fasting 70 – 120 it increases after 1 hour and returns back to fasting after 2 hours: • • The blood glucose never exceeds 170 mg/dl. • • No glucosuria. • In Diabetes mellitus: • the fasting is more than normal ( > 110 mg/dl or more ) and the curve takes 3 hours or more to return back to fasting level. • One or more samples exceed 180 mg/dl. • There is glucosuria.

  36. Diagnosis of DM • 3-Measurement of glycosylated –Hb (HbA1C) • Glycosylated Hb (HbA1c) results fromnon enzymatic binding of glucose with Hemoglobin .The process is irreversible and continues during the half life of RBCs. • Normal subjects and controlled cases of DM have 4-8% glycosylated –Hb. • The increase in the percent of HbA1c is related to the blood glucose level. • The test is used for follow up of diabetic patients. • Not affected byfasting or feeding or any factor that affect blood glucose immediately so it gives an idea aboutthe glycemic control of the patient throughout the life span of RBCs ( 120 days ).Also it gives an idea aboutthe efficiency of the drugs used in treatment and adjustment of proper dose.

  37. Other types of DM • 1- Diabetes insipidus: Deficiency of antiduretic hormone (ADH). Urine volume > 10 L/day, watery specific gravity 1003. • 2- Steroid diabetes: Long term treatment with glucocorticoids which cause hyperglycemia. Prolonged hyperglycemia causes exhaustion of β-cell of pancreas. • 3- Stress diabetes : Due to increased adrenaline in emotional states. • 4- Experimental diabetes; could be caused by : • • Alloxan • • Streptozotocin • • Dehydroascorbic acid • • Surgically by removal of pancreas

  38. Other types of DM Differences between diabetes mellitus and diabetes insipidus

  39. hypoglycemia

  40. It is the decrease of blood glucose level to less than 50 mg /dl.

  41. Importance The CNS is very dependent on a continuous supply of blood glucose as a fuel for energy.

  42. Symptoms Adrenergic symptoms mediated by epinephrine release Neuroglycopenicsymptoms (neuroglycopenia) Mediated by impaired delivery of glucose to the brain \ \ impairment of brain functions causing headache, confusion ,slurred speech, seizures, coma and even death • Anxiety • Palpitation • Tremors • sweating

  43. Causes Overdose of insulin (most common cause) Fasting hypoglycemia Postprandial hypoglycemia: \ \ Alimentary hypoglycemia due to exaggerated insulin release following a carbohydrates meal or after gastrectomy Liver cell failure (no glycogenolysis or gluconeogenesis) Chronic Alcoholism due to excessive alcohol intake with decreased food intake (no gluconeogenesis) Hereditary fructose intolerance : Ingestion of sucrose causes hypoglycemia due to accumulation of fructose -1-P which inhibits glycogenolysis by allosteric inhibition of liver phosphorylase enzyme. Adrenocortical insufficiency (Addison's disease). (glucocorticoids) Glycogen storage diseases (Von Gierke'sdisease) G-6-p can not leave liver (no G-6-phosphatase

  44. CH3-CH2OH → CH3-CHO  CH3-COOH →ACTIVE ACETATE - - Phosphofructokinase enzyme

More Related