why regulate plasma glucose? set point: 80-100 mg/100 ml plasma glucose is virtually the only fuel...
TRANSCRIPT
WHY REGULATE PLASMA GLUCOSE?
Set Point: 80-100 mg/100 ml plasma
•Glucose is virtually the only fuel the brain can use tomake ATP (also ketones)
•If plasma glucose falls too low, brain activity declines
•If plasma glucose rises too high, there are both acuteand longterm complications – diabetes mellitus
Absorptive state
Post absorptive state
HOW IS ALL THIS REGULATED?
HORMONES!
Hormones that decrease glucose Hormones that increase glucose
Insulin Glucagon
Epinephrine
Growth hormone
Cortisol
How come so many backup systems to prevent low plasma glucose?
Pancreas – insulin staining in brown
EFFECTS OF INSULIN
•Increased numbers of glucose transporters on cell surface
•Activation of enzymes involved in synthesis of glycogen, glycerol,fatty acids, activation of lipoprotein lipase
•Inhibition of enzymes involved in gluconeogenesis, glycogenolysis,conversion of triacylglycerides to fatty acids and glycerol,synthesis of ketones
Net effect = decreased plasma glucose
Absorptive state
Post absorptive state
What causes insulin to be released?
Hormones that decrease glucose Hormones that increase glucose
Insulin Glucagon
Epinephrine
Growth hormone
Cortisol
Effects of glucagon that lead to increased plasma glucose
Liver: • Activation of enzymes that cause gluconeogenesis• Activation of enzymes that promote ketone synthesis• Inhibition of enzymes that cause synthesis of glycogen
What causes glucagon to be released from the pancreas?
Hormones that decrease glucose Hormones that increase glucose
Insulin Glucagon
Epinephrine
Growth hormone
Cortisol
Hormones that decrease glucose Hormones that increase glucose
Insulin Glucagon
Epinephrine
Growth hormone
Cortisol
plasma glucose
Hypothalamus GHRH secretion
Anterior Pituitary
GH secretion
Liver Adipocytes Most cellsGluconeogenesis lipolysis glucose uptake
plasma glucose
fatty acids
Hormones that decrease glucose Hormones that increase glucose
Insulin Glucagon
Epinephrine
Growth hormone
Cortisol
Diabetes Mellitus• Juvenile/insulin dependent/Type I
– often follows viral illness– autoimmune attack on islets– decreased insulin production– Prevalence: 0.2-0.3% of the US population
• adult-onset/non-insulin dependent/Type II)– associated with obesity and older age– insulin levels can be normal or elevated, especially early– peripheral insulin resistance– Prevalence: 6-10% of the US population (and rising)
Genetics of Diabetes Mellitus
• Juvenile/insulin dependent/Type 1– More common in persons of Northern European descent– Sibling relative risk of about 15
• adult-onset/non-insulin dependent/Type 2)– Higher in persons of African, Pacific Island, and Native
American descent– Sibling relative risk of about 3-4– Many whole genome wide studies recently reported
identifying several risk loci
Type 1 diabetes
Acute Complications
• Hyperglycemia– Increased serum glucose leading to loss of water and glucose
in the urine– Hyperosmolarity– Hypotension– Hyperkalemia (increased serum potassium)– Ketosis
• Hypoglycemia– Resulting from overdose of insulin causing excessive uptake
of glucose by cells, manifestations include activation of the sympathetic nervous system
Insulin deficiency
glucose uptakegluconeogenesis
plasma glucose
lipolysis
ketone synthesis
plasma ketones
plasma H+
Brain dysfunction, coma, death
plasma osmolarity
Loss of Na+ andH2O in urine
Blood volume
Blood pressure
Brain blood flow
K+
Na+
K+
Na+
insulinadrenalinaldosterone
K+
K+
acidosisincreased osmolaritycell injury
Hyperkalemia in diabetes mellitus
Consequences of high plasma glucose
• Increased glycosylation of proteins– hemoglobin (useful as an index of average
blood glucose levels over last 3 months)– collagen in basement membrane
Consequences of high plasma glucose
• Distrubances in polyol pathways in cells that do not require insulin for glucose uptake (nerves, lens of the eye, kidney, blood vessels)
Glucose
aldose reductase
sorbitol Increased osmolarity swelling
Impaired ion pumps injury
Chronic Complications
• Atherosclerosis
• Microvascular disease– nephropathy– retinopathy
• Peripheral Neuropathy
• Infections– Leading cause of amputations
Diabetes & Atherosclerosis Potential Mechanisms
• Hypertension• Glycosylation of LDL (decreases liver
uptake)• Decrease in HDL (? via glycosylation)• Glycosylation/protein crosslinking as
cause of vessel injury• Defects in lipoprotein lipase• Enhanced platelet aggregation• Sorbitol accumulation in vessel wall
Diabetic Retinopathy• major cause of blindness
– 10% of type I after 30 yrs– Leading cause of new blindness in the US
• Nonproliferative lesions– BM thickening, edema, hemorrhage
• Proliferative lesions– new blood vessels, fibrous tissue– proliferate over retina over time– secondary to ischemia, microvascular disease– most severe seen in type I
CAUSES OF END STAGE RENAL DISEASE PERCENT OF CASES
Diabetes 34.2Hypertension 29.2Glomerulonephritis 14.2Interstitial nephritis 3.4Cystic kidney disease 3.4Other or unknown 15.4
Diabetic Nephropathy
• approx. 1/3 of type I DM will get renal failure
• Mechanism: basement membrane damage
Peripheral Neuropathy• Mechanisms:
– changes in nerve components (myelin, schwann cells, etc.)
– microvascular disease
• Consequences– pain, abnormal sensation in extremities– touch, pain sensation eventually lost--allows tissue
damage– autonomic nerve dysfunction
• GI tract motility• GU tract dysfunction
Foot ulcer
INFECTIONS
CAUSES OF INFECTIONS
•Decreased neutrophil function - due to high glucose
•More frequent skin eruptions - peripheral neuropathies
•Ischemia - vascular disease
•Increased plasma glucose - good growth medium for microorganisms
TREATMENT
• Juvenile/insulin dependent/Type I– Insulin injections
• adult-onset/non-insulin dependent/Type II)– Diet and exercise– Sulfonylureas (increase insulin release)– Thiazolidinediones (PPAR agonists) – glucophage (metformin) (increases insulin sensitivity)– Insulin (in severe cases when insulin has been depleted)