Treatment of Diabetes Mellitus

Question 1

Identify the main organs, and hormones involved in control of blood glucose. When are they produced, where, and what is their effect ?

Answer 1

1) Pancreas
GLUCAGON
-When: When blood glucose is low
-Where: alpha cells and upper GI
-Effect: stimulate glycogen breakdown and gluconeogenesis

INSULIN

• When: is blood glucose is high
• Where: Beta cells
• Effects: stimulates muscle and adipose tissue to uptake glucose redistributing Glut4 to the cell membrane

2) Liver
- Controls glucose levels through gluconeogenesis and glycogen synthesis

Question 2

Identify risk factors for type I diabetes.

Answer 2

• Genetic prediposition
• Exposure to viral infections
• Diet
• Vitamin D deficiency

Question 3

What proportion of beta cells need to be destroyed in order for clinical type 1 diabetes to present ?

Answer 3

• Clinical T1DM does not present until >80-90% of beta cells have been destroyed

Question 4

Describe clinical features and their timeline in type 1 diabetes.

Answer 4

• Clinical course of T1DM is characterised by the rapid onset of osmotic symptoms, including polyuria, polydipsia, nocturia, thirst, weight loss and fatigue along with hyperglycaemia (possibly also osmotic lens change), while being clinically dry, and having increased urinary ketones.
• Two thirds of patients present with life-threatening diabetic ketoacidosis at diagnosis (DKA)

Question 5

What is the main treatment option for type 1 diabetes ?

Answer 5

Insulin therapy (to replace deficient hormone)

Question 6

To what extent is genetic predisposition present in type 2 diabetes ?

Answer 6

Genetic predisposition may be present

Question 7

Identify risk factors for type 2 diabetes.

Answer 7

Metabolic syndrome (starts with energy imbalance, high food consumption, and low energy expenditure)
Stress

Question 8

Describe the pathology underlying type 2 Diabetes.

Answer 8

• Fat deposits in visceral organs leads to altered insulin signalling, insulin resistance and beta cell damage
• Often impaired insulin receptor signalling leads to insufficient transport of glucose into tissues

Question 9

What proportion of beta cells need to be destroyed in order for clinical type 2 diabetes to progress ?

Answer 9

• T2DM progresses when ~80-90% of beta cells fail

Question 10

What is the main treatment option for type 2 diabetes ?

Answer 10

• Principle for treatment: try to correct energy imbalance, increase sensitivity to insulin, increase natural insulin secretion, supplement with insulin, or decrease blood glucose

Question 11

When is each type of diabetes usually diagnosed ?

Answer 11

Type 1- in childhood

Type 2- in over 30 year olds

Question 12

To what extent are DM types 1 and 2 associated with excess body weight ?

Answer 12

Type 1- NOT associated with excess body weight

Type 2- YES associated with excess body weight

Question 13

To what extent are DM types 1 and 2 associated with higher than normal ketone levels at diagnosis ?

Answer 13

Type 1- Often associated with higher than normal ketone levels at diagnosis

Type 2- Often associated with high blood pressure and/or cholesterol levels at diagnosis

Question 14

To what extent can type 1 and 2 diabetes be controlled without medication ?

Answer 14

Type 1- Cannot be controlled without taking insulin

Type 2- Sometimes possible to come off diabetes medication

Question 15

Describe progression to type 2 diabetes.

Answer 15

• T2DM - there is a natural progression from prediabetes to diabetes, due to disruption of individual’s ability to metabolise glucose
• Individuals with prediabetes have lower insulin sensitivity that results in hyperinsulinemia (i.e. due to insulin resistance, plasma insulin has to increase). At the point where insulin resistance overcomes ability to make insulin, blood glucose begins to increase.
• Diabetes progresses when the beta-cells are failing, resulting in low insulin secretion in combination with low insulin sensitivity

Question 16

What amount of fasting plasma glucose indicates diabetes ? What amount of random glucose ?

Answer 16

• >7 mM Fasting plasma glucose = diabetes
OR
random glucose measurements about 11.1 mM

Question 17

How is blood glucose monitored ?

Answer 17

• Effective diabetes management is usually measured by self-monitoring of blood glucose through sampling capillary blood after a finger prick
-NICE recommends monitoring this 4 times a day for individuals with type 1 DM (one before each meal, and at bedtime)

2) HbA(1c) measurement is also used to diagnose diabetes and evaluate glucose levels over a longer time-frame

Question 18

How is HbA(1c) measurement useful for measuring blood glucose ?

Answer 18

• HbA1c provides an integrated measure of control over the lifespan of red blood cells ~120 days – levels above 7% indicate diabetes

Question 19

What range of glucose do we aim for in type 1 DM ?

Answer 19

• Aim in treating Type I diabetics - replacement therapy to normalize glucose levels 4-7 mM (pre- prandial/fasting).

Question 20

To what extent should individual glucose levels rise about 8 mM after a meal ?

Answer 20

• In normal individuals glucose level can rise higher than normal range 4-7 but should be <7.8 mM two hours after a meal

Question 21

At which blood glucose level will glucose be detected in the urine ?

Answer 21

• Blood glucose levels >10 mM will overload the renal capacity and be detected in the urine

Question 22

Identify the main kinds of insulin formulations which exist. State the duration of action of each.

Answer 22

• Rapid-acting soluble insulin: Insulin lispro, Insulin aspart, and Insulin glulisine- rapid onset (10-20 minutes) and short duration (2-5 hrs)
• Isophane insulin (Neutral Protamine Hagedorn; NPH) is an intermediate- acting insulin
• Insulin glargine is a longer acting designer Insulin
• Insulin detemir is a long-acting designer insulin
• Insulin degludec is a long-acting designer insulin

Question 23

What is the duration of action of insulin ?

Answer 23

• Durations of activity can be rapid-acting (within 15 min) to long-duration peakless forms (some active >24 hours)

Question 24

How is insulin administered ? Why ?

Answer 24

• Insulin is administered parentally because it is a protein that would be destroyed/digested by the gut if taken orally.
• For routine use it is given subcutaneously and by IV infusion in emergencies (only soluble forms)
• Can be given as a continuous subcutaneous infusion (CSII), giving background insulin (but also “allows for adjustable boluses to cover ingested carbohydrates”

Question 25

Describe the main dissolution properties of the main formulations of insulin.

Answer 25

• Insulin lispro, Insulin aspart, and Insulin glulisine- prevent dimer formation allowing more active monomers to be bioavailable
• Isophane insulin (Neutral Protamine Hagedorn; NPH)- recipitates into suspensions which slowly dissolve
• Insulin glargine- has decreased solubility at neutral pH - forms aggregates that slowly dissolve
• Insulin detemir- had a FA, a fatty acid, which confers albumin binding, which slowly dissociates prolonging circulation
• Insulin degludec- has a fatty acid, which results in multi-hexamer formation at injection site with slow release

Question 26

What proportion of type 2 DM patients use insulin ?

Answer 26

1/3

Question 27

Graph glucose infusion rate of the main types of insulin formations, over time.

Answer 27

Refer to slide 12

Question 28

When are fixed dose insulin therapies used ?

Answer 28

• A fixed dose therapy (i.e. amount of insulin taken at each meal does NOT vary from day to day) can help to simplify the understanding of blood glucose results but does not offer the flexibility of how much carbohydrate patients choose to consume at each meal

Question 29

When are flexilble dose insulin therapies used ?

Answer 29

• Flexible insulin therapy is used for patients that really understand glucose metabolism and gives patients more control of what they eat and how they balance their blood glucose levels but will take time and commitment to learn how best to adjust insulin doses
• On a flexible insulin therapy patients choose how much insulin to inject at each meal and also allows doses to be varied in response to different carbohydrate quantities in meals

Question 30

What is the main adverse effect of insulin therapy ?

Answer 30

• Main adverse effect of insulin therapy is hypoglycemia but for patients that have difficulty achieving good glycemic control they may need to use an insulin pump

Question 31

Identify the main types of insulin therapy with regards to number and kind of doses per day.

Answer 31

1, 2, 3 injections/day

Basal-bolus

Insulin pump (CSII).

Question 32

State the number of injections, time of injections, suitability to DM types, formulations, meal time and content, and requirement of patient understanding for:
1, 2, 3, injections/day.

Answer 32

1, 2, 3 INJECTIONS/DAY

• Number of injections: 1-3
• Time of injections: Morning or at meals
• Suitability: T2D
• Formulations: Rapid-acting or short-acting insulin is mixed w/ intermediate insulin
• Meal time and content: Fixed
• Required patient understanding: More basic

Question 33

State the number of injections, time of injections, suitability to DM types, formulations, meal time and content, and requirement of patient for:
Basal-bolus therapy

Answer 33

BASAL-BOLUS

• Number of injections: Multiple
• Time of injections: Throughout the day
• Suitability: T1D, some T2D
• Formulations: Intermediate or long acting with short acting formulation
• Meal time and content: Flexible
• Required patient understanding: High

Question 34

State the number of injections, time of injections, suitability to DM types, formulations, meal time and content, and requirement of patient for:
Insulin Pump (CSII)

Answer 34

INSULIN PUMP (CSII)

• Number of injections: semi-automated (as needed)
• Time of injections: Throughout the day
• Suitability: T1D
• Formulations: Short acting insulin formulation
• Meal time and content: Flexible
• Required patient understanding: Medium/high

Question 35

Identify the main drugs used in type 2 DM.

Answer 35

ORAL HYPOGLYCEMIC AGENTS 
INCRETIN MIMETICS
DPP-4 INHIBITORS
INSULIN SECRETAGOGUES
SGLT2 INHIBITORS
THIAZOLINEDINEDIONES 
ALPHA GLUCOSIDATE INHIBITORS

Question 36

Identify an example of oral hypoglycemic agent. Describe its mechanism of action.

Answer 36

Metformin

•Mechanism of action: can potentiate residual insulin and insulin sensitivity + acts to reduce gluconeogenesis in the liver (markedly increased in type 2 DM and oppose the actions of glucagon) + increases glucose uptake and utilization in skeletal muscle + slightly delays carb absorption in the gut + increases FA oxidation + can encourage weight loss by suppressing appetite + alters energy metabolism

Question 37

How does increasing FA oxidation help metformin control type 2 DM ?

Answer 37

• Increases fatty acid oxidation - reduces circulating LDL and VLDL, which can help in obesity associated diabetes and atherosclerosis development

Question 38

Identify a possible side effect of Metformin.

Answer 38

In rare cases can cause anorexia

Question 39

Explain how Metformin alters energy metabolism. How quick or slow is this ?

Answer 39

METFORMIN alters energy metabolism:

• Acts on the mitochondria to change ratio of AMP to ATP
• Increased AMP:ATP ratios activate AMP-activated protein kinase (cells metabolic master switch)
• This inhibits glucagon signaling and gluconeogenic pathways
• AMPK increases transcription of genes important for glucose transport, fatty oxidation, and inhibits FA synthesis

TAKE TIME DUE TO REGULATION GENE NETWORKS

Question 40

What type of cells secrete GLP-1 ? GIP ?

Answer 40

• Glucagon-like peptide-1 (GLP-1) is secreted by L-cells in the gut
• Gastric inhibitory peptide (GIP) secreted by K-cells in gut

Question 41

What is the main action of incretins ?

Answer 41

• Incretins stimulate insulin biosynthesis/ secretion, inhibit glucagon secretion in pancreas, delay gastric emptying, increase cardiac output and increase brain satiety signals + also indirectly increase insulin sensitivity in muscle and decrease gluconeogenesis in liver

Question 42

How are incretins degraded ?

Answer 42

• Incretins are rapidly degraded by an enzyme called dipeptidyl peptidase-4 (DPP-4)I

Question 43

Identify the main examples of incretin mimetics. Which incretin does each of these mimic ?

Answer 43

• Exenatide, Exenatide LAR, and Liraglutide- analogs of exendin-4/GLP-1

Question 44

What is the main mechanism of action of incretin mimetics ? What is their route of administration?

Answer 44

• Incretin analogs lowers blood glucose after a meal by increasing insulin secretion and suppressing glucagon secretion.
• Given subcutaneously (SC) as peptide analogs.

Question 45

Identify side effects of incretin mimetics.

Answer 45

• Can cause hypoglycemia and a range of gastrointestinal effects.

Question 46

Identify main indications of incretin mimetics.

Answer 46

• Used for type 2 diabetes in addition to oral agents to improve control and aid weight loss.

Question 47

What are the main differences between Exenatide and Exenatide LAR ?

Answer 47

• Exenatide is given twice daily, but can cause nausea

* Exenatide LAR is a long-acting release formulation that is administered weekly and induces less nausea

Question 48

What is the structural specificity of Liraglutide ? How does this aid its action ?

Answer 48

• Liraglutide has an additional fatty side-chain that confers albumin binding and slows renal clearance

Question 49

Identify examples of DPP-4 inhibitors.

Answer 49

• Sitagliptin and vildagliptin

Question 50

What is the mechanism of action of DPP-4 inhibitors ?

Answer 50

• Enhance endogenous incretin effects by blocking DPP-4

* Lowers blood glucose by increasing first phase of insulin response after meals.

Question 51

What are the main indications for DPP-4 inhibitors ?

Answer 51

• Used in type 2 diabetes in addition to other oral hypoglycaemic drugs.

Question 52

Identify the side effects of the main DPP-4 inhibitors.

Answer 52

• Sitagliptin is well tolerated and weight neutral.
• Vildagliptin is not available in the USA - found associated with respiratory tract infections, headache and on occasion serious pancreatitis.

Question 53

Identify the main insulin secretagogues.

Answer 53

Sulphonylureas (e.g. Tolbutamide, Chlorpropamide, Glibenclamide, Glipizide)

Meglitinides (Repaglinide and Nateglinide)

Question 54

Describe the mechanism of action of Sulphonylureas, and Meglitinides.

Answer 54

SULPHONYLUREAS
• Sulphonylureas interfere with beta cell ion channels to potentiate insulin secretion.

MEGLITINIDES
• Similar mechanism of action as Sulphonylureas (blocking KATP channels to ↑insulin release)

Question 55

Identify the main indications of Suphonylureas.

Answer 55

• Used in early stages of type 2 diabetes – as they require functional b cells
• Can be combined with Metformin and Glitazones.

Question 56

Identify any side effects of Sulphonylureas, and Meglitinides.

Answer 56

SULPHONLUREAS
• Well tolerated but can lead to weight gain by stimulating appetite
• Can interact with other drugs to produce severe hypoglycaemia due to competition for metabolising enzymes, plasma binding proteins, and excretory pathways

MEGLITINIDES
• Short duration of activity leads to lower risk of hypoglycaemia

Question 57

State a condition which is required for Sulphonylureas to work.

Answer 57

Only work if b cells of the pancreas are functional.

Question 58

How do Sulphonylureas interfere with beta cell ion channels to potentiate insulin secretion ?

Answer 58

• High affinity receptors for these drugs are present in b- cell membranes.
• Block ATP-sensitive potassium channels in b- cells.
• Causes beta cell depolarisation, which leads to insulin secretion.

Question 59

Identify examples of SGLT2 inhibitors.

Answer 59

• Canagliflozin, dapagliflozin, empagliflozin

Question 60

Identify indications for SGLT2 inhibitors.

Answer 60

Used in T2D as monotherapy when diet and exercise alone is not adequate for whom metformin is contraindicated or inappropriate.

Question 61

Describe mechanism of action of SGLT2 inhibitors.

Answer 61

• Block glucose reabsorption by the proximal tubule leading to therapeutic glucosuria
• Controls glycaemia independently of insulin pathways
• Lead to reduced HbA1c up to 1.17% compared to placebo –

Question 62

Identify side effects of SGLT2 inhibitors.

Answer 62

• Well tolerated, reduce weight and reduce systolic blood pressure
• Do not cause hypoglycaemia but associated with increased risk of urinary tract infections

Question 63

Identify an example of Thiazolidinediones.

Answer 63

Pioglitazone

Question 64

What class of drugs do Thiazolidinediones belong to ?

Answer 64

Thiazolidinediones are Peroxisome proliferator activated receptor – gamma ( PPARgamma - a nuclear receptor) agonists

Question 65

Where is the Peroxisome proliferator activated receptor expressed ?

Answer 65

PPARgamma expressed in adipose tissue, muscle and liver.

Question 66

Identify the main indications for Pioglitazone.

Answer 66

• Pioglitazone increases insulin sensitivity and lowers blood glucose in type 2 diabetics
• Pioglitazone is used in the clinic as an additive to other oral hypoglycaemic drugs such as metformin and Sulphonylureas

Question 67

Describe mechanism of action of Pioglitazone.

Answer 67

• Reduces the amount of exogenous insulin needed by about 30%
• Increases glucose uptake into muscle in response to insulin
• Reduces blood glucose and free fatty acid concentrations
• Promote transcription of several genes with products that are important in insulin signalling ( lipoprotein lipase, fatty acid transporters, Glut-4 and others) but take months to work

Question 68

Identify side effects of Pioglitazone.

Answer 68

• Can cause weight gain and fluid retention

* Has been linked to bladder cancer, heart failure, and osteoporotic fractures

Question 69

Identify an example of alpha-Glucosidase inhibitor.

Answer 69

Acarbose

Question 70

Describe the mechanism of action of Acarbose (an alpha-Glucosidase inhibitor).

Answer 70

• Competitive inhibitor of intestinal alpha-glucosidase

* Delays carbohydrate absorption in the small intestine reducing the postprandial spike in glucose

Question 71

Identify the main indications for Acarbose (an alpha Glucosidase inhibitor).

Answer 71

Used in type 2 diabetes often in combination with other hypoglycaemics

Question 72

Identify side effects of Acarbose (an alpha Glucosidase inhibitor).

Answer 72

Side effects can include flatulence and diarrhea