Endocrine Pharmacology Lecture Notes (Antidiabetic Drugs) PDF

Summary

This document is a lecture about endocrine pharmacology, specifically focusing on antidiabetic drugs. It covers topics like diabetes mellitus (types 1 and 2), insulin, and its mechanism of action and regulation. The lecture is aimed at second-year dental students.

Full Transcript

Endocrine pharmacology

(Antidiabetic drugs)

By

Dr. Hamza Al Asbily

For
nd
2 year dental students
Diabetes mellitus (DM)
is a clinical syndrome characterized by hyperglycemia due to absolute or
relative deficiency of insulin. Lack of insulin affects the metabolism of
carbohydrate, protein and fat.

Type 1 diabetes mellitus: It appears when more than 90% of cells of
pancreas are destroyed by an autoimmune process. The onset is acute and
the peak incidence is around 15 years. Insulin is essential for all patients
with type-1 DM.

Type 2 diabetes mellitus: It is the commonest form of diabetes where
genetic influence , Overeating, obesity, underactivity and ageing are the
main risk factors. Type-2 DM is associated with increased hepatic
production of glucose and resistance of target tissues to the action of
insulin.

Insulin is a protein consisting of two amino acid chains, alpha (21 aa) and
beta (30 aa) connected by two disulfide bridges. Insulin is synthesized as a
precursor (pro-insulin) which is enzymatically cleaved in P cells into C
peptide and mature insulin which are stored in granules.

Insulin receptor & mechanism of action
Insulin binds to specific receptors (receptor tyrosine kinase) present on the
cell membrane. The receptor consists of 2 and 2 subunits.Binding of
insulin to the receptor activates tyrosine kinase of the receptor. A complex
series of events occur resulting in various actions of insulin.
Regulation of insulin secretion
1. Chemical: Glucose, amino acids and fatty acids in the blood stimulate
cell to release insulin.

2. Neural: Both parasympathetic and sympathetic fibers supply the islet
cells. Parasympathetic stimulation causes increase in insulin secretion and
lowers raised blood sugar level.

3. Hormonal: GLP-1 (glucagon-like peptide), GIP (GI inhibitory peptide),
gastrin, secretin, cholecystokinin, etc. promote the secretion of insulin.
Actions of insulin
Insulin has profound effects on the metabolism of carbohydrate, fat and
protein. Insulin facilitates the entry of glucose into all cells of the body.
However, entry of glucose into red blood cells (RBCs), white blood cells
(WBCs), liver and brain cells can occur independent of insulin. Muscular
exercise also facilitates entry of glucose into muscle cells without the need
for insulin.

1. Insulin inhibits hepatic glycogenolysis, gluconeogenesis and lipolysis in
adipose tissue.

2. Insulin promotes protein synthesis in muscle, lipogenesis, hepatic and
muscle glycogenesis.

3. Insulin also promotes peripheral utilization of glucose and K+ uptake into
the cells.

Pharmacokinetics
Insulin is destroyed by proteolytic enzymes in the gut and, hence, is not
effective orally. Insulin is administered usually by subcutaneous (s.c.) route;
but in emergencies, regular (soluble) insulin is given by i.v. route. After i.v.
injection, soluble insulin is rapidly metabolized by the liver and kidney with
a half-life of about 6 min.

Insulin sources and preparations
1. Animal insulin

2. Human insulin: They are produced by recombinant DNA technology

3. Insulin analogues: They are produced by DNA recombinant technology
where they are obtained following alteration of amino acid sequence of
human insulin.

Insulin classification according to the onset and duration
of action

Site of administration
Insulin is usually administered subcutaneously in the abdomen, buttock,
anterior thigh or dorsal arm. In emergency regular insulin is administrated
by intravenous rout.
Indications of Insulin Therapy
1. Type 1 DM.

2. Type 2 DM. : insulin is added if diet regulation & exercise plus metformin
or other oral antidiabetics fail to control hyperglycemia.

3. DM with pregnancy & lactation: To avoid risk of drug (S)-induced

hypoglycemia in fetus & newborn.

4. DM with stress & emergency: regular insulin is used in diabetic
ketoacidosis, surgery, infection, myocardial infarction or severe psychic
stress (oral hypoglycemic fail to control hyperglycemia as in stress
conditions (.

5. DM with severe liver or renal disease: To avoid risk of hypoglycemia by
sulfonylurea.

6. Treatment of hyperkalemia: Insulin enhances k+ influx into cells.

N.B.: Insulin use in pregnancy, lactation, stress, emergency or hyperkalemia
is temporary.

Adverse effects of insulin
1. Hypoglycemia is the most common and dangerous complication.

Treatment: All these manifestations are relieved by administration of
glucose. If the patient is conscious, oral glucose or if the hypoglycemia is
severe (unconscious patient) 50 mL of 50% dextrose is injected
intravenously. Glucagon 1 mg i.v. or adrenaline 0.2 mg s.c. may be given for
severe hypoglycemia.

2. Allergic reactions ( rare).

3. Lipodystrophy (either atrophy or hypertrophy) may occur at the site of
injection. It may be avoided by using purified insulin preparations and
changing the injection site by rotation.
4. Insulin resistance: It is a state in which patient requires more than 200 U
of insulin/day and is common among obese type-2 diabetics.

5. hypokalemia.

Drug interactions
1. B.blockers : by masking the symptoms of hypoglycemia.

2. Salicylates : Salicylates exert hypoglycemic effect by increasing the
sensitivity of pancreatic B-cells to glucose and potentiating insulin
secretion.

Other antidiabetic Drugs
1. Sulfonylurea

Sulfonylureas are divided into two generations. All have the same
mechanism of action, but differ in potency and duration of action. The
second-generation drugs are more potent than first generation drugs.

Mechanism of action
They act primarily by stimulation of insulin secretion from pancreatic B-cells
(main mechanism). In addition they may increase peripheral sensitivity and
reduce glucagon release(minor mechanism).
Note: For successful therapy with sulfonylureas, at least 30% functioning B-
cells are necessary. Sulfonylureas are ineffective in type-1 DM because of
absence of functioning B-cells in the islets of pancreas.

Pharmacokinetics
Sulfonylureas are well absorbed after oral administration, highly bound to
plasma proteins and have low volume of distribution. They are metabolized
in liver and excreted mainly in urine.

Adverse effects
1. Hypoglycemia is common, particularly with long acting agents
(glibenclamide and chlorpropamide) so glibenclamide is best avoided in
elderly patients because of the high risk of hypoglycemia.

2. GIT disturbances.

3. Weight gain.

4. Allergic reactions.

Use: Sulfonylureas are useful in patients with type 2 diabetes mellitus.

Drug interactions
1. salicylates/sulphonamides: These drugs are highly bound to plasma
proteins and displace sulfonylureas from the plasma protein-binding site
resulting in an increase in free plasma concentration of sulfonylureas
therefore potentiate the effects of sulfonylureas (severe hypoglycemia).

2. B.blockers :by masking the symptoms of sulfonylurea induced
hypoglycemia.

3. Rifampicin, Phenobarbitone : Rifampicin and Phenobarbitone are
enzyme inducers; hence, they accelerate the metabolism of sulfonylureas
and reduce their effects.
2. Meglitinides (repaglinid and nateglinide)
Repaglinid and nateglinide are structurally unrelated to sulfonylureas, but
their mechanism of action is similar to sulfonylureas. They have rapid onset
but short duration of action. They are less potent than sulfonylureas. They
are used only in type-2 DM to control postprandial hyperglycemia.

3. Biguanides (metformin)

Mechanism of action
1. inhibit hepatic gluconeogenesis.

2. inhibit alimentary absorption of glucose.

3. increase peripheral utilization of glucose and decrease lipogenesis in
adipose tissue.

Note: Metformin does not affect insulin release therefore It is not
associated with weight gain or hypoglycemia even at high dose.

Pharmacokinetics
Metformin is taken orally, well absorbed through GI tract and is excreted
mostly unchanged in urine.

Adverse effects
Adverse effects are metallic taste, anorexia, nausea, vomiting, diarrhea (GIT
symptoms are the most common) and skin rashes. Lactic acidosis is the
most serious complication , but is rare with metformin. Prolonged use can
cause vitamin B12 deficiency due to malabsorption.

Use
1. Type 2 diabetes. 2. Polycystic ovary syndrome.
4. Thiazolidinedione (Pioglitazone & rosiglitazone)

Pharmacokinetics
Pioglitazone is almost completely absorbed from GI tract, highly bound to
plasma proteins (95%) and metabolized in the liver.

Adverse effects
Nausea, vomiting, anemia, weight gain, edema and precipitation of heart
failure in patients with low cardiac reserve; rarely hepatotoxicity has been
reported. In addition the use of these drugs is associated with increased
risk of bladder cancer.

Use: Pioglitazone is used alone or in combination with antidiabetic drugs in
patients with type-2 diabetes.
5. alpha-glucosidase Inhibitors (Acarbose & Meglitol )
They reduce intestinal absorption of carbohydrates by inhibiting the
enzyme alpha -glucosidase in the brush border of the small intestine and
reduce postprandial hyperglycemia. They are mainly used in obese type-2
DM patients. Side effects are mainly on GI tract: flatulence, fullness and
diarrhea.

Newer Drugs

1. GLP-1 receptor agonists, e.g. exenatide
Glucagon like peptide-1 (GLP-1) is released from the gut after meals. It
stimulates insulin secretion, suppresses glucagon release and slows gastric
emptying. It is degraded by dipeptidyl peptidase 4 (DPP-4); its plasma half-
life is 1–2 minutes. GLP-1 receptor agonists, e.g. exenatide, are resistant to
DPP-4. Their actions are similar to GLP-1. It is used in patients with type-2
diabetes mellitus.

2. DPP-4 (dipeptidyl peptidase–4) inhibitors, e.g. sitlagliptin,
saxagliptin
They inhibit the enzyme DPP-4 prevent inactivation of GLP-1 increase
plasma concentration of GLP-1 increases insulin secretion, suppresses
glucagon release, slows gastric emptying and improves control of
postprandial hyperglycemia. They are administered orally in patients with
type 2 diabetes mellitus.

3. sodium glucose cotransporter 2 inhibitors (SGLT2 inhibitors,
Gliflozins)
Glucose is freely filtered across glomerulus and is reabsorbed in proximal
tubules by sodium glucose co-transporter-2 [SGLT-2]. Dapagliflozin and
canagliflozin are taking orally and act by inhibiting this transporter and
cause glycosuria in diabetics. These also result in weight loss.
Use: Gliflozins are used for treatment of type 2 diabetes.

Adverse effects
genital and urinary tract infections are the most common adverse effects.