PANCREAS Dr. Zainab H.H. Dept. of physiology College of medicine Al-Nahrain University.
Pancreas applied physiology
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Transcript of Pancreas applied physiology
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Pancreas(Applied Physiology)DANISH HASSANLECTURER, UNIVERSITY OF SARGODHA
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PancreasHyper-secretion Hyper-insulinism
Hypo-secretion Diabetes Mellitus
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Diabetes Mellitus Diabetes mellitus is a metabolic disorder
characterized by high blood glucose level, associated with other manifestations.
In most of the cases, diabetes mellitus develops due to deficiency of insulin.
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Classification Of Diabetes Mellitus Several forms of diabetes mellitus, which occur due
to different causes. Diabetes may be:
1. Primary: Diabetes that is unrelated to another disease.
2. Secondary: Diabetes that occurs due to damage or disease of
pancreas by another disease or factor.
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Recent classification divides primary diabetes mellitus into two types:
1. Type I DM2. Type II DM
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Type I Diabetes Mellitus It is due to deficiency of insulin because of
destruction of β-cells in islets of Langerhans. This type of diabetes mellitus may occur at any age
of life. But, it usually occurs before 40 years of age and the
persons affected by this require insulin injection. Also called insulin-dependent diabetes mellitus
(IDDM).
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When it develops at infancy or childhood, it is called juvenile diabetes
It develops rapidly and progresses at a rapid phase.
It is not associated with obesity, but may be associated with acidosis or ketosis.
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Causes of Type I diabetes mellitus Degeneration of β-cells in the islets of Langerhans
of pancreas by viral or auto-immune disease. Congenital disorder of β-cells
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Other forms of type 1 diabetes mellitus1. Latent autoimmune diabetes in adults
(LADA): LADA or slow onset diabetes has slow onset and
slow progress than IDDM and it occurs in later life after 35 years.
It may be difficult to distinguish LADA from type II diabetes mellitus, since pancreas takes longer period to stop secreting insulin.
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2. Maturity onset diabetes in young individuals (MODY):
It is a rare inherited form of diabetes mellitus that occurs before 25 years.
It is due to hereditary defects in insulin secretion.
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Type II Diabetes Mellitus It is due to insulin resistance (failure of insulin
receptors to give response to insulin). So, the body is unable to use insulin. About 90% of diabetic patients have type II
diabetes mellitus. It usually occurs after 40 years.
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Only some forms of Type II diabetes require insulin.
In most cases, it can be controlled by oral hypoglycemic drugs.
Also called Non-insulin dependent diabetes mellitus (NIDDM).
Type II diabetes mellitus may or may not be associated with ketosis, but often it is associated with obesity.
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Causes for type II Diabetes Mellitus Structure and function of β-cells and blood level of insulin are
normal. But insulin receptors may be less, absent or abnormal,
resulting in insulin resistance. Common causes of insulin resistance are:
1. Genetic disorders (significant factors causing type II diabetes mellitus)
2. Lifestyle changes such as bad eating habits and physical inactivity, leading to obesity
3. Stress
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Insulin resistance is part of cascade of syndrome called the “metabolic syndrome."
Some of the features of the metabolic syndrome include:
1. Obesity, especially accumulation of abdominal fat;2. Insulin resistance;3. Fasting hyperglycemia; 4. Lipid abnormalities, such as increased blood triglycerides
and decreased blood high-density lipoprotein-cholesterol; 5. Hypertension
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Other forms of type II diabetes mellitus1. Gestational diabetes:
It occurs during pregnancy. It is due to many factors such as hormones secreted
during pregnancy, obesity and lifestyle before and during pregnancy.
Usually, diabetes disappears after delivery of the child. However, the woman has high risk of development of
type II diabetes later.
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Secondary Diabetes Mellitus Secondary diabetes mellitus is rare and only
about 2% of diabetic patients have secondary diabetes.
It may be temporary or may become permanent due to the underlying cause.
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Causes of secondary diabetes mellitus1. Endocrine disorders such as gigantism, acromegaly
and Cushing’s syndrome, polycystic ovarian syndrome
2. Damage of pancreas due to disorders such as chronic pancreatitis, cystic fibrosis and hemochromatosis (high iron content in body causing damage of organs)
3. Pancreatectomy (surgical removal)4. Liver diseases such as hepatitis C and fatty liver
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5. Autoimmune diseases such as celiac disease6. Excessive use of drugs like antihypertensive
drugs (beta blockers and diuretics), steroids, oral contraceptives, chemotherapy drugs, etc.
7. Excessive intake of alcohol and opiates.
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Signs and Symptoms of Diabetes Mellitus Various manifestations of diabetes mellitus develop
because of three major setbacks of insulin deficiency.1. Increased blood glucose level (300 to 400 mg/dL)
due to reduced utilization by tissue2. Mobilization of fats from adipose tissue for energy
purpose, leading to elevated fatty acid content in blood. This causes deposition of fat on the wall of arteries and development of atherosclerosis
3. Depletion of proteins from the tissues.
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Following are the signs and symptoms of diabetes
1. Glucosuria2. Osmotic diuresis3. Polyuria4. Polydipsia5. Polyphagia6. Asthenia
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7. Acidosis8. Acetone breathing9. Kussmaul breathing10. Circulatory shock11. Coma
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Glucosuria It is the loss of glucose in urine. Normally, glucose does not appear in urine. When glucose level rises above 180 mg/dL (renal
threshold level for glucose in blood) glucose appears in urine
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Osmotic diuresis The diuresis caused by osmotic effects. Excess glucose in the renal tubules develops
osmotic effect. Osmotic effect decreases the reabsorption of
water from renal tubules, resulting in diuresis. It leads to polyuria and polydipsia
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Polyuria Excess urine formation with increase in the
frequency of voiding urine is called polyuria. It is due to the osmotic diuresis caused by
increase in blood glucose level.
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Polydipsia Increase in water intake is called polydipsia. Excess loss of water decreases the water content
and increases the salt content in the body. This stimulates the thirst center in hypothalamus. Thirst center, in turn increases the intake of
water.
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Polyphagia Polyphagia means the intake of excess food. It is very common in diabetes mellitus.
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Asthenia Loss of strength is called asthenia. Body becomes very weak because of this. Asthenia occurs due to protein depletion, which is
caused by lack of insulin. Lack of insulin causes decrease in protein
synthesis and increase in protein breakdown, resulting in protein depletion.
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Protein depletion also occurs due to the utilization of proteins for energy in the absence of glucose utilization.
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Acidosis During insulin deficiency, glucose cannot be utilized
by the peripheral tissues for energy. So, a large amount of fat is broken down to release
energy. It causes the formation of excess ketoacids, leading
to acidosis. One more reason for acidosis is that the ketoacids are
excreted in combination with sodium ions through urine (ketonuria).
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Sodium is exchanged for hydrogen ions, which diffuse from the renal tubules into ECF adding to acidosis.
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Acetone Breathing In cases of severe ketoacidosis, acetone is
expired in the expiratory air, giving the characteristic acetone or fruity breath odor.
It is a life-threatening condition of severe diabetes.
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Kussmaul breathing Kussmaul breathing is the increase in rate and
depth of respiration caused by severe acidosis.
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Circulatory Shock Osmotic diuresis leads to dehydration, which
causes circulatory shock. It occurs only in severe diabetes.
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Coma Due to Kussmaul breathing, large amount of carbon
dioxide is lost during expiration. It leads to drastic reduction in the concentration of
bicarbonate ions causing severe acidosis and coma. It occurs in severe cases of diabetes mellitus. Increase in the blood glucose level develops hyper-
osmolarity of plasma which also leads to coma. It is called hyperosmolar coma.
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Diabetic ketoacidosis It is an acute pathologic event characterized by
elevated blood glucose levels and ketone bodies and metabolic acidosis
It results directly from decreased insulin availability and simultaneous elevations of the counter regulatory hormones glucagon, catecholamines, cortisol, and growth hormone.
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In diabetic ketoacidosis, gluconeogenesis in the liver proceeds unopposed by the physiologic presence of insulin.
The excess blood glucose increases osmolarity, which, if severe, can result in diabetic coma.
Low insulin levels and the high levels of counterregulatory hormones glucagon, epinephrine, and cortisol combine to increase the activity of hormone-sensitive lipase, increase the release of free fatty acids, and decrease the activity of acetyl-CoA carboxylase, thereby impairing the reesterification of free fatty acids and promoting fatty acid conversion into ketone bodies.
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The steps involved in ketogenesis are β-oxidation of fatty acids to acetyl-CoA, formation of acetoacetyl-CoA, and conversion of acetoacetyl-CoA to 3-hydroxy-3-methylglutaryl- CoA and then to acetoacetate, which is then reduced to 3-hydroxybutyrate.
Acetoacetate can be spontaneously decarboxylated to acetone, a highly fat-soluble compound that is excreted slowly by the lungs and is responsible for the fruity odor of the breath of individuals with diabetic ketoacidosis.
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Ketone bodies released into the blood can freely diffuse across cell membranes and serve as an energy source for extrahepatic tissues including the brain, skeletal muscle, and kidneys.
Ketone bodies are filtered and reabsorbed in the kidney.
At physiologic pH, ketone bodies, with the exception of acetone, dissociate completely.
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The resulting liberation of H+ from ketone body metabolism exceeds the blood’s buffering capacity, leading to metabolic acidosis with an increased anion gap.
If severe, this condition can lead to coma
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Changes in blood constituents in diabetic acidotic coma
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Diabetic Comas Diabetic Coma
1. Hypoglycemic coma It is a result of treatment and not a manifestation of
the disease itself. It is usually mild enough to be reversed by eating of
drinking carbohydrates.
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2. Dibetic ketoacidosis coma3. Non ketotic hyperosmolar coma
Blood glucose level above 900mg/dL, causing severe osmotic diuresis resulting in dehayration.
Normal blood osmolarity is between 280-300mmol/kg and when it rises above 340 mmol/kg the conscious level is disturbed.
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Complications of Diabetes Mellitus Prolonged hyperglycemia in diabetes mellitus
causes dysfunction and injury of many tissues, resulting in some complications.
Development of these complications is directly proportional to the degree and duration of hyperglycemia.
However, the patients with well controlled diabetes can postpone the onset or reduce the rate of progression of these complications.
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Vascular complications are responsible for the development of most of the complications of diabetes such as:
Cardiovascular complications like: Hypertension Myocardial infarction
Degenerative changes in retina called diabetic retinopathy
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Degenerative changes in kidney known as diabetic nephropathy
Degeneration of autonomic and peripheral nerves called diabetic neuropathy.
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Diagnostic Tests for Diabetes Mellitus Diagnosis of diabetes mellitus includes the
determination of:1. Fasting blood glucose2. Postprandial blood glucose3. Glucose tolerance test (GTT)4. Glycosylated (glycated) hemoglobin.5. Urine glucose level testing
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Glucose Tolerance Test in a normal and Diabetic Person
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Treatment for Diabetes Mellitus
Type I diabetes mellitus Treated by exogenous insulin. Since insulin is a polypeptide, it is degraded in GI
tract if taken orally. So, it is generally administered by subcutaneous
injection.
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Type II diabetes mellitus Type II diabetes mellitus is treated by oral
hypoglycemic drugs. Patients with longstanding severe diabetes
mellitus may require a combination of oral hypoglycemic drugs with insulin to control the hyperglycemia.
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Oral hypoglycemic drugs are classified into three types:
1. Insulin Secretagogues These drugs decrease the blood glucose level by
stimulating insulin secretion from β-cells. Sulfonylureas (tolbutamide, gluburide, glipizide)
are the commonly available insulin secretagogues
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2. Insulin Sensitizers These drugs decrease the blood glucose level by
facilitating the insulin action in the target tissues. Examples are biguanides (metformin) and
thiazolidinediones (pioglitazone and rosiglitazone)
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3. Alpha Glucosidase Inhibitors These drugs control blood glucose level by inhibiting
α-glucosidase. This intestinal enzyme is responsible for the
conversion of dietary and other complex carbohydrates into glucose and other monosaccharides, which can be absorbed from intestine.
Examples of α-glucosidase inhibitors are acarbose and meglitol
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Hyperinsulinism Hyperinsulinism is the hypersecretion of insulin.
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Cause of Hyperinsulinism Hyperinsulinism occurs due to the tumor of β-
cells in the islets of Langerhans.
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Signs and Symptoms of Hyperinsulinism
1. Hypoglycemia Blood glucose level falls below 50 mg/dL.
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2. Manifestations of central nervous system CNS manifestation occurs when blood glucose level
decreases. All the manifestations are together called
neuroglycopenic symptoms. Initially, the activity of neurons increases, resulting in
nervousness, tremor all over the body and sweating. If not treated immediately, it leads to clonic
convulsions and unconsciousness.
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Slowly, the convulsions cease and coma occurs due to the damage of neurons