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Carbohydrates • Monosaccharides D-glucose D-galactose Reducing substance: hydroxyl group near an aldehyde or ketone group can react with Cu2+, converting it to Cu+ D-glucose D-fructose • Disaccharides reducing end Lactose reducing end Maltose Sucrose not a reducing substance • Polysaccharides reducing end Cellulose Amylopectin Glycogen branches about every 24-30 linear linkages branches every 8-12 glucose units Intestinal absorption of carbohydrates Jejunum villi microvilli Intestinal absorption of carbohydrates GUT Starch Glycogen a -amylase maltose 1 saliva and pancreatic juice sucrose 2 lactose galactose Monosaccharides glucose fructose 3 MICROVILLI BRUSH BORDER glucose fructose galactose BLOOD Glucose Production Glucose Consumption Blood glucose 125g brain Glucose 50g Glycogen (75%) 50g rbc wbc muscle fat cell Glucose transporters Name Tissue Function GLUT1 (erythrocyte) wide distribution, esp. brain, kidney, colon, fetal tissues Basal glucose transport GLUT2 (liver) Liver, b-cells of pancreas, small intestine, kidney Non-rate-limiting glucose transport GLUT3 (brain) Wide distribution, esp. neurons, placenta, testis Glucose transport in neurons GLUT4 (muscle) Skeletal muscle, cardiac muscle, adipose tissue Insulin-stimulated glucose transport* GLUT5 (small intestine) Small intestine, kidney, skelatal muscle, brain, adipose tissue Fructose transport *insulin low…GLUT4 in intracellular compartments; insulin high…GLUT4 translocates to membrane Glucose Production Glucose Consumption Blood glucose CO2 125g brain Glucose 50g Glycogen (75%) 50g pyruvate lactate (10-15%) certain amino acids (10-15%) glycerol (2%) fat cell rbc wbc CO2 muscle Regulation of blood glucose • Glycogenesis: glucose glycogen (liver, muscle) • Glycogenolysis: glycogen • Gluconeogenosis: non-CHO sources • Glycolysis: glucose glucose glucose CO2 + H2O + ATP • Renal threshold: proximal convoluted tubule Regulation of blood glucose stimulates Somatostatin inhibits d a b Pancreatic Islet Cortisol Growth hormone glucose glucagon Insulin epinephrine Glycogenolysis Gluconeogenesis Liver Glucose uptake Lipogenesis Adipose tissue Glucose uptake Glycolysis Muscle Determination of glucose • Specimens used – whole blood » used with home glucose monitoring units » cellular use of glucose gives 7% decrease/hour » NaF preserves glucose 24 hr, RT • cannot use such a specimen for enzyme assays, especially urease » lithium iodoacetate preserves glucose; does not interfere with urease » capillary blood = fasting venous level + 5 mg/dL – plasma, serum » 10-15% higher level than whole blood glucose » RI: 70-105 mg/dL – CSF » RI: 60-70% plasma glucose = 40-70 mg/dL – urine » RI: <30 mg/dL random; <500 mg/24 hr Glucose Methods • hexokinase glucose + ATP gluc-6-PO4 + NAD+ INT + NADH + H+ – – – – HK G6PD PMS gluc-6-PO4 + ADP 6-phosphogluconate + NADH + H+ formazan + NAD+ most widely used reference method against which others are compared serum, plasma and urine avoid hemolysis Glucose Methods • glucose oxidase glucose + O2 GO H2O2 + reduced dye gluconic acid + H2O2 POD oxidized dye + H2O • peroxidase reaction interference by uric acid, vitamin C, bilirubin • suitable for spinal fluid measure O2 consumption via pO2 electrode • suitable for all body fluids measure H2O2 production via H2O2 electrode • suitable for plasma, serum, whole blood Glucose Methods • glucose dehydrogenase GDH glucose + NAD+ D-gluconolactone + NADH + H+ » highly specific as “GDH-NAD”, with little interference, EXCEPT… • Pyrroloquinolinequinone (“GDH-PQQ”) – 2005 FDA warning – giving false increased glucose readings when patient is receiving maltose, icodextrin (dialysis), galactose, d-xylose Manufacturer Proper Name Sugar Octapharma Immune Globulin Intravenous (Human) Maltose10% Talecris Immune Globulin Intravenous (Human) Maltose9-11% Cangene Rho(D) Immune Globulin Intravenous (Human) Maltose10% Cangene) Vaccinia Immune Globulin (Human Maltose10% NERL Diagnostic d-Xylose Usual dose 25g Baxter Peritoneal dialysis soln (icodextrin) 7.5 mg/dL icodextrin Glucose Methods • glucose dehydrogenase GDH glucose + NAD+ D-gluconolactone + NADH + H+ » highly specific as “GDH-NAD”, with little interference, EXCEPT… • Pyrroloquinolinequinone (“GDH-PQQ”) – 2005 FDA warning – giving false increased glucose readings when patient is receiving maltose, icodextrin (dialysis), galactose, dxylose » Coulometry • • • • http://www.medisense.com/au FreeStyle glucometer, Abbott Laboratories Electrons released in the reaction are measured as a current Allows very small volume (0.3 uL) to be used, with results in 15 seconds Glucose Methods • oxidation-reduction reactions Fe3+ Fe2+ or Cu2+ • least specific for glucose Cu1+ Clinical Significance • Hyperglycemia – diabetes mellitus – endocrine disorders » acromegaly: incr. growth hormone » Cushing’s syndrome: incr. cortisol » thyrotoxicosis: incr. T4 » pheochromocytoma: incr. epinephrine – drugs » certain anesthetics » steroids Clinical Significance • Hypoglycemia – insulin overdose – drugs » sulfonylureas » antihistamines – alcoholism (long term) – insulinoma – galactosemia – glycogen storage diseases Expert Committee on the Diagnosis and Classification of DM - 2005 • Diagnosis of Diabetes Mellitus – Symptoms of diabetes mellitus » Polyuria » Polydipsia » Unexplained weight loss – Any TWO of the following tests, on different days » Casual plasma glucose > 200 mg/dL » Fasting plasma glucose (FPG) > 126 mg/dL » 2hr Post prandial glucose (PPG) > 200 mg/dL after a meal with 75g glucose load Expert Committee on the Diagnosis and Classification of DM - 2005 • Type 1 – Type 1a » characterized by beta cell destruction caused by an autoimmune process, usually leading to absolute insulin deficiency » patients must take insulin to survive » usually young, with acute onset (days to weeks) » islet-cell antibodies usually present – Type 1b » idiopathic Expert Committee on the Diagnosis and Classification of DM - 2005 • Type 2 – insulin resistance in peripheral tissue and an insulin secretory defect of the beta cell – variable [insulin] – highly associated with a family history of diabetes, older age (>40), obesity and lack of exercise – more common in » Women » African American » Hispanics » Native Americans Expert Committee on the Diagnosis and Classification of DM - 2005 • “Other specific types” – pancreatic, hormonal disease – Pancreatitis, cystic fibrosis – Acromegaly (GH), Cushing’s syndrome (cortisol) – drug/chemical toxicity – insulin receptor abnormalities – no renal or retinal complications Expert Committee on the Diagnosis and Classification of DM - 2005 • Gestational diabetes mellitus – – – – – – pregnancy frequent but transitory glucose intolerance greater risk of perinatal complications placental lactogen? > 140 mg/dL one hour after 50-g glucose load screening TWO of four results abnormal in 100 g glucose load test: – fasting plasma glucose > 105 mg/dL – > 195 mg/dL at 1 hr – > 165 mg/dL at 2 hrs – > 145 mg/dL at 3 hrs National Diabetes Association 2003 • Pre-diabetes http://diabetes.niddk.nih.gov/dm/pubs/diagnosis/index.htm http://www.diabetes.org/pre-diabetes.jsp Fasting Plasma Glucose Result (mg/dL) 70 – 99 100 to 125 126 and above Diagnosis Normal Pre-diabetes (impaired fasting glucose) Diabetes mellitus* *Confirmed by repeating the test on a different day. Clinical Significance • Glucose tolerance test (still used for gestational diabetes diagnosis) – patient preparation » normal diet three days prior to test » no food after regular evening meal on day before test » take fasting blood, urine specimen » drink 100 g glucose load within 5 minutes » allow water, but no food, chewing gum, smoking, exercise during test » specimens taken 1, 2, 3 hours after ingestion 200 Plasma glucose (mg/dL) Diabetic Normal 100 60 120 Minutes after glucose ingestion 180 Clinical Significance • Other conditions, tests associated with diabetes mellitus – white cell antigens » HLA types DR3, DR4, DQB1*0302 » Note that diabetes resistance genes = DR2, DQB1*0602 – lipid studies » hyperlipoproteinemia type IV • increased TG – microalbuminuria – microangiopathies » retinal, renal, neural Management of diabetes mellitus • Glycated hemoglobin (A1) COOH H2N COOH H2N COOH H2N COOH H2N COOH H2N COOH H2N N glu N glu non-enzymatic process conversion of HbA into HbA1 at N-terminal valine Management of diabetes mellitus • Glycated hemoglobin – irreversible reaction occurring throughout the 120-day life span of rbc – reflects timed average [glucose] over previous 4-8 weeks – HbA1c = 80% total glycohemoglobin – reference range: 3-6% total Hgb – uncontrolled diabetes mellitus: 12-20% total Hgb – controlled: 9-12% total Hgb • Considerations when measuring HbA1c – abnormal hemoglobins can also be glycated – variability in levels of “labile fraction” (intermediates) Management of diabetes mellitus For every 1% decrease in HbA1c, risk of microvascular complications is reduced by 35% Diabetes Care 2000, 23: S27-S31 Management of diabetes mellitus • Manual Methods for HbA1c compared Ion-exchange chromatography Principle “Fast fraction” HbA1c elutes first + + + HbA + + + Affinity Chromatography + + HbA1c + -- - - - - - - ------ -- - - HbA1c elutes last HbA--Val--N | CH2 | C=O | HOCH pba | pba HCOH | pba HCOH | CH2OH pba Phenylboronic acid Management of diabetes mellitus • Manual Methods for HbA1c compared – other non-glycated Hb measured » IEC: HbF and any others with charge like A1 » AC: none – time » IEC: 2-3 hrs » AC: 15 minutes – glycated hemoglobins measured » IEC: A1a, 1b, 1c only » AC: any glycated hemoglobin, including abnormals – temperature sensitive? » IEC: yes » AC: no Management of diabetes mellitus • Automated Method for HbA1c – High pressure liquid chromatography (HPLC) – Cation exchange method » the eluant must be __________________ » The first form of hemoglobin eluting from the column must be _________________________ » The last form of hemoglobin eluting from the column must be __________________________ Management of diabetes mellitus • Attempts to convert HbA1c value to “mean blood glucose” value – Nathan et al, 1984 using linear regression on data from 21 patients – 33.3 (%HbA1c) – 86 – Examples: 6.0% = ~115 mg/dL 7.5% = ~165 mg/dL 9.0% = ~215 mg/dL Management of diabetes mellitus • Revised calculation, effective 3/21/05 – Rohlfing et al, 2002 using comparison data from 1500 patients – (35.6 x %HbA1c) – 77.3 – Examples: 6.0% = ~136 mg/dL 7.5% = ~190 mg/dL 12.0% = ~350 mg/dL – Only valid for A1c values between 6 and 12% Management of diabetes mellitus • Glycated serum proteins – albumin (“fructoseamine”) – turnover = 2-3 weeks – rapid method using tetrazolium dye reduction colored product Carbohydrate inborn errors of metabolism • Glycogen storage diseases – – – – lack of enzymes of glycogen metabolism incr. tissue glycogen results in severely limited lifespan von Gierke’s disease » liver cells lack glucose-6-phosphatase glucose-6-PO4 triose phosphate pyruvate blood glucose Carbohydrate inborn errors of metabolism • Lactose intolerance – – – – – deficiency in intestinal mucosal lactase GTT done as baseline 2nd day, give lactose instead of glucose normal: normal GTT curve abnormal: flat curve ( and much pain!) Carbohydrate inborn errors of metabolism • Galactosemia (1) galactose galactose-1-PO4 galactilol (2) galactose-1-PO4 * UDP-galactose (3) UDP-galactose UDP-glucose (4) UDP-glucose glucose-1-PO4 cataracts – deficiency in uridyl transferase * – results in galactosuria, retardation, cataracts, no conjugation of bilirubin – urine tests gal. oxidase galactose + O2 galactose dialdehyde + H2O2 Ketones • Complication of uncontrolled diabetes mellitus – Acid-base imbalance – Can be life-threatening – Acetone, acetoacetate, b-hydroxybutyrate Blood ketones fatty acids Ketones acetoacetate B-hydroxybutyrate acetate acetyl CoA amino acids CO2 TCA cycle H2O ATP Ketones • Complication of uncontrolled diabetes mellitus – Sodium nitroprusside – B-hydroxybutyrate dehydrogenase Blood ketones fatty acids Ketones acetoacetate B-hydroxybutyrate acetate acetyl CoA amino acids CO2 TCA cycle H2O ATP Extra slides Glycogenesis, glycogenolysis • Hormones involved – fed: insulin from pancreatic beta cells (Islets of Langerhans) » preproinsulin proinsulin (A, B and C peptides) insulin + C-peptide » anabolic (synthesis) » promotes cellular uptake of glucose » increased: • lipogenesis • protein synthesis • glycogenesis » decreased: • lipolysis • ketone formation • gluconeogenesis • glycogenolysis Glycogenesis, glycogenolysis • Hormones involved – fasting: glucagon from pancreatic alpha cells » catabolic » liver: glycogen converted to glucose, released into blood » muscle: glycogen converted to glucose-6-PO4, remains in the muscle cell for its own energy needs – “fight or flight” : epinephrine from adrenal medulla » action similar to glucagon Glycogenesis, glycogenolysis • Stimulation of insulin release – – – – glucose leucine, arginine, histidine, phenylalanine sulfonylureas (tolbutamides) ACTH, GH • Inhibition of insulin release – thiazide diuretics – dilantin (antiseizure) – human placental lactogen (diabetes of pregnancy) • Decreased tissue response to insulin – glucocorticoids – estrogens – progestins obesity inactivity low CHO diet Gluconeogenesis • cortisol (hydrocortisone) – from adrenal cortex – inhibits glucose entry into muscle, connective tissue, lymphoid tissue – stimulates release of gluconeogenic amino acids from muscle – promotes conversion of amino acids into glucose by liver – stimulates lipolysis in adipose cells, releasing glycerol for conversion to glucose by liver • ACTH – from anterior pituitary – stimulates production of cortisol Glycolysis • NOTE!! – if serum/plasma is not separated from cells soon after collection, cellular use of glucose will continue, causing a falsely decreased glucose result Renal Threshold • proximal convoluted tubule – reabsorbs all glucose if <180 mg/dL – glycosuria results if blood glucose >180 mg/dL
