Lect 15 Endocrine Pancreas, Diabetes & Therapeutics PDF

Summary

These lecture notes provide an overview of the endocrine pancreas, covering topics such as pancreatic islets, the regulation of blood glucose, insulin and glucagon, and types of diabetes mellitus, including their causes and treatments.

Full Transcript

THE ENDOCRINE PANCREAS,
DIABETES MELLITUS &
PHARMACOTHERAPEUTICS
PANCREATIC ISLETS

The pancreas is a flattened organ located posterior and slightly
inferior to the stomach and can be classified as both an
endocrine and an exocrine gland
Histologically, it consists of pancreatic islets or islets of
Langerhans and clusters of cells (acini) (enzyme-producing
exocrine cells)
 Anatomy of Pancreas

Organ (5 inches) consists of head, body & tail
Cells (99%) in acini produce digestive enzymes
Endocrine cells in pancreatic islets produce hormones
Cell Organization in Pancreas

Exocrine acinar cells surround a small duct
Endocrine cells secrete near a capillary
Histology of the Pancreas

1 to 2 million pancreatic islets per human
pancreas (1-2% of weight)
Contains 4 types of endocrine cells
Cell Types in the Pancreatic Islets
(Islets of Langerhans)

Alpha cells (20%) produce glucagon
Beta cells (70%) produce insulin (+ amylin)
Delta cells (5%) produce somatostatin
PP cells produce pancreatic polypeptide

Human pancreas contains 8 mg of insulin;
secretes 0.5 to 1 mg per day.
Insulin rapidly destroyed by liver & kidney (t½
in circulation about 6 minutes)
 Regulation of Blood Glucose
When blood glucose increases, pancreas secretes a hormone
called INSULIN to bring glucose to normal levels.
Glucose enters ß-cells via GLUT2 glucose transporter
ATP synthesis increases
ATP-sensitive potassium (KATP) channels close
Insulin is released
Insulin reduces blood glucose

When blood glucose is low, pancreas secretes a hormone called
GLUCAGON to maintain the levels constant.
Glucagon increases blood glucose

Insulin and glucagon have opposing actions.
 Primary targets for insulin action
Liver
Skeletal muscle
Adipose tissue
Pancreatic alpha cells (to inhibit glucagon release)

NB: skeletal muscle and fat dependent on insulin for glucose uptake
Insulin promoting
+ counter-regulatory hormones
Glucagon-like peptide-1 (GLP-1) and glucose-dependent
insulinotropic polypeptide (GIP), from GI tract, increase prandial
insulin release (= “incretin” effect)
Amylin inhibits hepatic gluconeogenesis
Glucagon, catecholamines (i.e. noradrenaline, adrenaline),
glucocorticoids (e.g. cortisol) & growth hormone oppose insulin
action
Regulation
Regulation of glucagon and
insulin secretion is via
negative feedback
mechanisms
Low blood glucose
stimulates release of
glucagon
High blood glucose
stimulates secretion of
insulin
INSULIN

Isolated in 1921 by Banting and Best
Sequenced in 1955 by Sanger
Gene on chromosome 11 in humans
Human gene isolated and used to make human
insulin from bacteria
Insulin contains 2 chains. A chain 21 amino
acids and B chain 30 amino acids. Only one
amino acid different between pig & man.
STRUCTURE OF BOVINE INSULIN
SYNTHESIS OF INSULIN

Insulin synthesised in RER of ß islet cells as
preproinsulin
23 amino acids removed to form proinsulin in
RER
In Golgi apparatus proinsulin packed into
vesicles where it is cleaved into insulin & C
peptide
Released by exocytosis when high blood sugar
present in blood.
INSULIN ACTIONS

Hormone of abundance (anabolic hormone)
Actions via insulin receptor include:
Stimulated uptake of glucose in insulin-sensitive
tissue like skeletal muscle and fat (via GLUT4
glucose transporter)
Stimulated glycogen synthesis
Stimulated lipid synthesis
Stimulated protein synthesis
Stimulated DNA/RNA synthesis
Stimulated glycolysis
AMYLIN

37 amino acid protein
Co-released with insulin
Actions in CNS
Inhibits glucagon release
Slows gastric emptying
Decreases food intake
Cleared by kidneys (t½ in circulation about 10 minutes)
GLUCAGON
Fasting hormone & hormone of energy release
(catabolic)
Secreted by α islet cells
29 amino acid linear polypeptide
Synthesized as preproglucagon
Degraded by liver and kidneys (t½ in circulation about 6
minutes)

Actions (mainly on liver):
Increases glycogen breakdown in liver
Lipolytic action
Increases ketone body formation by liver
Increases gluconeogenesis in liver
INSULIN ACTIONS

Synthesis Breakdown

Protein ↑ ↓

Lipid ↑ ↓

Glycogen ↑ ↓

DNA/RNA ↑ ↓

Liver Gluconeogenesi Glycolysis↑
s↓
GLUCOSE TRANSPORTERS
GLUCOSE TRANSPORT
PANCREAS SUMMARY

The endocrine pancreas mainly produces insulin and glucagon
Insulin and glucagon control blood glucose levels
Lack of insulin results in diabetes mellitus
Diabetes mellitus can be divided into Type 1 & 2
Diabetes mellitus can be treated with diet, exogenous insulin and
additionally in Type 2 DM, various hypoglycaemic drugs.
DIABETES
Two diseases:
Diabetes insipidus (posterior pituitary disease)
Diabetes mellitus (pancreas disease)
first described by the Egyptians in 550 BC
“diabetes” is Greek meaning pass through or siphon used
in 200 AD
“mellitus” means honey sweet, added in 1700s

Two major types of diabetes mellitus:
Type 1
Type 2
 Diabetes Mellitus
Main Signs & Symptoms are:
Polyuria (increase urine volume)
Polydipsia (increase drinking)
Polyphagia (increased appetite)
Hyperglycaemia (raised blood sugar)
Glycosuria (glucose in urine)
Ketosis (ketone bodies in blood & urine)*
Acidosis (excess acid in blood)
Rapid weight loss*
Weakness, drowsiness, fatigue
Skin problems (e.g. infections, diabetic dermopathy)
Visual problems (e.g. blurred vision)
Coma

Due to absolute (type 1) or relative (type 2) lack of insulin
*particularly in uncontrolled Type 1 DM
 Criteria for diagnosing diabetes
Diabetes symptoms plus:

a random venous plasma glucose concentration ≥ 11.1
mM or

a fasting plasma glucose ≥ 7 mM or

2h plasma glucose concentration ≥ 11.1 mM 2h after 75g
anhydrous glucose in an oral glucose tolerance test
(OGTT)

NB: in situations where HbA1c testing is appropriate, an
HbA1c of 48 mmol/mol (6.5%) is recommended as the cut-
off point for diagnosing diabetes
CAUSES OF DIABETES MELLITUS
1. Autoimmune – destruction of B cells (Type 1 DM
often)
2. Excess insulin “antagonists” e.g. growth hormone
3. Insulin receptor problems / insulin resistance
(Type 2 DM often)
4. Defective insulin release (Type 2 DM often)
5. Abnormal insulin produced
6. Drug & chemical damage
7. Pancreatitis
8. Problems with glucose transport
TYPES OF DIABETES MELLITUS
TYPE 1 TYPE 2
Onset Under 30yr Over 40yr
Type of onset Abrupt Gradual
Obesity at onset Rare Common
Symptoms Polyuria etc. Often none
Ketosis Frequent Rare
Endogenous insulin Negligible Present
ß islet cells Few Normal
Insulin therapy All need 20-30% need
Hypoglycaemic drugs Not used Can help
Diet Must control Must control
% diabetic 10 90
Family history Uncommon Common
HLA associated Yes No
Seasonal trends Yes No
Possible causes ß-cell loss (viral, chemical Insulin resistance (defective
means) insulin receptor signalling)
Vascular problems Microvascular Macrovascular
Sex ratio Same More female
 DIABETES MELLITUS
acute complications e.g.:

diabetic ketoacidosis (particularly uncontrolled Type 1 DM)
hyperglycaemia
Hyperosmolar Hyperglycaemic State (HHS) (associated with Type 2 DM)
iatrogenic hypoglycaemia
 DIABETES MELLITUS
chronic complications e.g.:

retinopathy (eye problems)
neuropathy (nerve damage)
nephropathy (kidney problems)
heart attack & stroke (atherothrombotic problems)
diabetic foot (circulatory problems)
gum disease (infection & circulatory problems)
increased cancer risk (tumorigenesis problems)
sexual dysfunction (nervous & circulatory problems)
DIABETES MELLITUS THERAPY
Type 1 DM
- treat with exogenous insulin + diet control
- compensates for absolute lack of endogenous insulin
Type 2 DM – various possibilities:
1. Dietary therapy especially if overweight
2. Drug therapy + diet control
3. Exogenous insulin + diet control
- addresses e.g. insulin resistance, inappropriate hepatic glucose
production & insulin secretory defect
 PHARMACOTHERAPEUTIC MANAGEMENT OF DIABETES: CLASSES
OF ANTI-DIABETIC AGENTS
Exogenous insulin preparations**
e.g. REGULAR INSULIN, INSULIN LISPRO, INSULIN GLARGINE
Inhibitors of glucose absorption (“starch blockers”)*
a-glucosidase inhibitors, e.g. ACARBOSE
Enhancers of glucose excretion*
gliflozins e.g. DAPAGLIFLOZIN
Insulin secretagogues*
sulfonylureas e.g. TOLBUTAMIDE, GLIPIZIDE
meglitinides (glinides) e.g. REPAGLINIDE
Glucagon-like peptide 1 (GLP-1), “incretin”-based therapy
GLP-1 agonists** e.g. EXENATIDE, LIRAGLUTIDE
inhibitors of dipeptidyl peptidase-4 (DPP-4)* e.g. SITAGLIPTIN
Insulin sensitisers*
thiazolidinediones (TZDs) (aka glitazones) - PIOGLITAZONE
biguanides - METFORMIN

*orally active; **administered by injection
 Common insulin preparations
Prandial bolus (short / *rapid acting)
Regular (unmodified insulin)
Lispro*
Aspart*
Glulisine*
Basal (intermediate / **long acting)
Neutral Protamine Hagedorn (NPH)
Glargine**
Detemir**
Insulin therapy

Indicated in Type 1 DM + Type 2 DM insufficiently
responsive to diet and oral hypoglycaemic agents
Administered by subcutaneous injection
Typically, basal preparation to provide constant,
low-level, background insulin throughout
day/night + prandial bolus preparation before
meals
Regimen (e.g. insulin preparation, dose,
frequency) personalised and adjusted for e.g.
patient’s activity, meals, blood glycaemia
SULPHONYLUREAS

Insulin secretagogues, i.e. stimulate islet ß cells
to release insulin (in glucose-independent
manner)
E.g. tolbutamide, glipizide, glimepiride
Bind to SUR1 subunit on ATP-dependent
potassium (KATP) channel, thus blocking channel
leading to depolaristion and stimulating
(glucose-independent) insulin release
Main side effects e.g.: raised insulin levels,
hypoglycaemia (especially in elderly), weight
gain, appetite stimulation, GI upset, skin rash,
blood dyscrasias
MEGLITINIDES (GLINIDES)

Insulin secretagogues, i.e. stimulate islet ß cells to
release insulin (in glucose-independent manner)
E.g. repaglinide
Similar site and mechanism of action as sulphonylureas,
but more selective for ß cell KATP channels
Rapid onset and offset kinetics with short duration of
action
Less potent than sulphonylureas
Reduce postprandial hyperglycaemia
Usually administered before main meal
Similar main side effect profile as for sulphonylureas, but
lower risk of hypoglycaemia and weight gain
BIGUANIDES
Metformin
Insulin sensitiser, inhibitor of hepatic glucose output (predominant
action in liver to reduce glycogenolysis and gluconeogenesis) and
inhibitor of glucose absorption from gut
Activates hepatic adenosine 5’-monophosphate (5-AMP)-activated
protein kinase (AMPK)
Increases insulin receptor activity and reduces insulin resistance
Enhances insulin effects in target tissues (muscle, fat, liver) and
increases insulin-dependent glucose uptake (muscle and fat)
No weight gain/some weight loss; reduces insulin levels and appetite;
low risk of hypoglycaemia (monotherapy); reduces lipids and glucagon
levels
Main side effects e.g.: GI upset, altered taste, decreased appetite,
vitamin B12 deficiency, lactic acidosis
STARCH BLOCKERS

Inhibit α-glucosidase enzymes in gut, blocking
starch and sucrose breakdown and
reducing/delaying glucose absorption from gut
E.g. acarbose
No weight gain
Low risk of hypoglycaemia (monotherapy)
Reduces postprandial hyperglycaemia
Main side effects: GI upset, flatulence,
aminotransferase elevation, raised triglycerides
Poorly tolerated, but tolerance can develop
THIAZOLIDINEDIONES (TZDs)/GLITAZONES

Pioglitazone
Insulin sensitiser
Stimulate nuclear hormone receptor PPAR-g
(peroxisome proliferator activated receptor g), with
predominant action in muscle
Reduce peripheral insulin resistance
Low risk of hypoglycaemia (monotherapy); reduces
insulin levels, triglycerides and free fatty acids
Main side effects e.g.: weight gain, fluid retention,
oedema, anaemia, GI upset, headache, fatigue,
potential liver toxicity (need to monitor), heart failure,
raised LDL cholesterol
 GLIPTINS
Inhibit dipeptidyl peptidase-4 (DPP-4) enzyme
“Incretin”-based therapy (“incretin” enhancers)
raise levels of GLP-1
E.g. sitagliptin, saxagliptin, vildagliptin, linagliptin
Enhance glucose-dependent insulin release, decrease
glucagon release + hepatic glucose production, delay
gastric emptying
Low risk of hypoglycaemia (monotherapy); no weight
gain
Main side effects e.g.: upper respiratory tract infection,
headache, GI upset, nasopharyngitis, raised creatinine
levels
 GLP-1 agonists
Analogues of GLP-1 (DPP-4 resistant)
“Incretin”-based therapy (“incretin” agonists)
mimic actions of GLP-1
E.g. exenatide, lixisenatide, liraglutide, dulaglutide,
semaglutide, tirzepatide*
Enhance glucose-dependent insulin release, decrease
glucagon release + hepatic glucose production, delay
gastric emptying
Appetite suppression; weight loss
Main side effects e.g.: GI disturbances, gastro-oesophageal
reflux disease, hypoglycaemia, headache, dizziness
* also a GIP agonist
GLIFLOZINS

Sodium glucose-linked transporter-2 (SGLT-2)
inhibitors
E.g. dapagliflozin, canagliflozin, empagliflozin,
ertugliflozin
Prevent proximal tubular reabsorption of filtered
glucose from renal filtrate
Low risk of hypoglycaemia (monotherapy); weight
loss
Main side effects e.g.: polyuria, dehydration,
aggravated glycosuria, genital yeast infection, urinary
tract infection, skin infection (Fournier’s gangrene),
diabetic ketoacidosis