Type 1 Diabetes

Question 1

Why is Type 1 Diabetes important?

Answer 1

Type 1 Diabetes affects 0.5% of Australians = 140,000

but…

Its incidence is rising

It carries a significant burden of disease and high risk of heath complications; particularly to the retina, kidneys and RBCs

It is largely diagnosed in childhood but is a life-long condition with continued treatment through adulthood

Question 2

What is the pathophysiology behind Type 1 diabetes?

Answer 2

Type 1 diabetes is an absolute deficiency of insulin arising from autoimmune attacks that destroy pancreatic þ-cells

The consequences of insulin deficiency are:

• Hyperglycaemia
• Uncontrolled lipolysis; and
• Elevated protein catabolism

This commonly presents as weight loss associated with polyuria and polydipsia

Question 3

Describe and illustrate the “stages” in the development of Type 1 diabetes

Answer 3

Question 4

How are beta-islet cells destroyed in Type 1 diabetes?

Answer 4

**The fundamental immune abnormality in type 1 diabetes is a failure of self-tolerance in T cells specific for islet antigens. **

This failure of tolerance may be a result of some combination of defective:

• Primary tolerance=clonal deletion of self-reactive T cells in the thymus,
• Peripheral tolerance= deficit is functions of regulatory T cells or resistance of effector T cells to suppression by regulatory cells.

Thus, autoreactive T cells not only survive but are poised to respond to self-antigens.

The activated T cells traffic to the pancreas, where they cause β-cell injury. T_H1 cells (which may secrete cytokines, including IFN-γ and TNF, that injure β cells), and CD8+ CTLs (which kill β cells directly) are involved

Question 5

What is the role of insulin auto-antibodies in type 1 diabetes?

Answer 5

Insulin auto-antibodies are one of the dominant signs of diabetes patients

They are not thought to be part of the pathogenesis of T1DM ( not clear )

They are used as a marker of T1DM presence and severity

The risk of getting T1DM at the age of 15 increases with the number of the different types of insulin auto-antibodies:

• None = 0.4%
• 1 = 12.7%
• 2 = 61.6%
• 3 = 79.1%

There is a subclinical period between the time auto-antibodies are detectable to the time at which clinical features of T1DM present

Question 6

What can be seen histologically when viewing islet cells of the pancreas of a T1DM patient?

Answer 6

1. Reduced insulin staining
   * progressive loss of beta islet cells and their ability to produce, store and release insulin
2. Evidence of chronic inflammation

• CD4+ & CD8+ lymphocytes in and around the islets
• CD8+ T-cells contain perforin and granzyme B that are thought to mediate a significant portion of pancreas damage.

Question 7

How would you describe the pattern of islet loss over time with T1DM?

Answer 7

Islet loss is patchy, even in the years after diagnosis.

Question 8

What is the association between autoimmune polyendocrine syndrome type 1 (APS-1 Syndrome) and T1DM?

Answer 8

**Autoimmune polyendocrine syndrome type 1 (APS-1 ) **is a syndrome characterised by the loss of central tolerance following mutations to the AIRE gene.

The AIRE gene is found cell of the thymus and is responsible for the transcription of organ specific antigens expressed by non-thymus cells -> ensuring that tolerance against all antigens can be developed; not just thymus antigents.

18% of patients with APS-1 develop T1DM

The syndrome leads to many different endocrine autoimmune disorders such as Addison’s disease, Hypothyroidism and mucocutaneous candidiasis.

Question 9

What is the association between immunodysregulation polyendocrinopathy enteropathy X-linked syndrome (IPEX) and T1DM?

Answer 9

**Immunodysregulation polyendocrinopathy enteropathy X-linked syndrome (IPEX) **is an autoimmune disease resulting from the loss of peripheral tolerance.

It arises from mutations to the FoxP3 gene which controls the functions of regulatory T-cells.

It is rare

**80% of children with the syndrome develop T1DM **

Question 10

What environmental triggers may activate autoimmunity in patients (with or without T1DM)?

Answer 10

• UV
• Diet
• Drugs
• Hygiene
• Infection
• Tissue specific causes

Question 11

What is C peptide?

Answer 11

C peptide or connecting peptide is a protein that connects the A-chain and B-chain of insulin molecules in the proinsulin molecule

It is commonly used as a **measure of endogenous insulin production. **

C-peptide levels are measured instead of insulin levels because C-peptide can assess a person’s own insulin secretion even if they receive insulin injections.

Question 12

What is wrong with current T1DM treatments?

Answer 12

Current diabetes treatment revolves around the administration of exogenous insulin into the body to maintain blood glucose.

This form of treatment is incapable of mimicking physiological glucose control and therefore can’t prevent complications of hypoglycaemic attacks and long term exogenous dependence.

Patients must inject themselves with insulin mutiple times a day -> is burdensome

Is not a cure

Question 13

What treatments for T1DM are in development for the future?

Answer 13

Ideally, a cure to abolish the disease by correcting autoimmunity is a long term objective of therapy development.

In the mean time, treatment being developed include:

• Islet transplantation
• Artifical pancreas

Question 14

What are the benefits of islet transplantation in the treatment of T1DM?

Answer 14

1. Islet cells can be manufactured reproducibly at multiple site using a common manufacturing process
2. * Independence from exogenous insulin* is achieved in half of all islet recipients at one year following infusion - with one or two infusions needed
3. Glycaemic control is excellent - even when full insulin indepence is not achieved
4. Hypoglycaemia awareness is treated effectively by transplantation - giving freedom from hypoglycaemic events.

**Hypoglycaemia is uncommon in patients with iselt transplants **

Question 15

What are the problems with islet transplantation?

Answer 15

1. Availability of organ donors
2. Viability and function of islets are variable
3. Immunosuppression treatment is required
4. The longevity of graft function
5. Allo-sensitisation = hypoxia to islets during the transplant conversion is problematic
6. Cost

Question 16

What are the treatment goals of islet transplantation?

Answer 16

Primarly Goals

• Good glycaemic control ( HbA1c < 6.5%)
• Freedom from hypoglycaemia

Secondary Goals

• Insulin independence
• Progressive decrease in exogenous insulin dose

Question 17

Who is suitable for an islet transplantation?

Answer 17

Patients who suffer severe hypoglycaemia:

• following all conventional therapies
• HYPO score > 1000
• hypoglycaemia unawareness

Question 18

What kinds of improvements are being made to islet transplanration moving forward into the future?

Answer 18

• Using new cells
  
  • Embryonic stem cells
  • Xenotransplantations
• New sites
• Oxygenation of tissue during transplantation process
• Co-transplantation with other cells
• New drug regimes
  
  • ​Developing antigen specific tolerance drugs rather than convential global immunosuppression that predisposed to developing cancer and infections

Question 19

In what year did Australia begin producing insulin of T1DM?

Answer 19

1923

Question 20

List the different types of replacement insulin available for T1DM treatment

Answer 20

1. Long acting insulin
2. Short acting insulin
3. Pre-mixed insulin
4. Insulin pumps

Question 21

What is a typical insulin regime?

Answer 21

The typical insulin regime is the Basal Bolus

• 1x injection with long acting insulin at bed time ( normally Glargine or Determir )
  
  • should last 24 hours
• 1x injection of short acting insulin immediately prior to each meal (** normally Aspart, Lispro or Glulisine)**
  
  • ​mimics the actions of natural insulin at each meal time

Question 22

What genetic modifications were made to the insulin replacements Glargine and Detemir to improve their functions?

Answer 22

Glargine

​Has an A-chain substitution from Asparagine (Asn) to Glycine (Gly) -> increases the insulins affintity and interaction with albumin = gives longer therapeutic action

Also has two Arginines bound to B30

Detemir

B30 deleted and replaced with a fatty chain -> allows the insulin replacement to better cross the BBB and inhibit drive for food.

Question 23

What do insulin pumps provide?

Answer 23

Insulin pumps deliver short acting insulin continuously at a background rate - eliminating the need for a long acting supplement - and the patient presses a button to deliver a bolus prior to every meal.

This an example of an open loop -> the pump is unable to respond to changes blood glucose in the body.

Question 24

How does an artificial pancreas differ from an insulin pump?

Answer 24

An articficial pancreas would be an insulin pump + a continuous glucose sensor to regulate the flow of insulin form the pump.

This represents a **closed loop system **where blood glucose would be continuously and automatically regulated - like a natural pancreas.

Difficulty: developing the algorithms relating to blood levels and insulin release.

Ideally -> develop a bi-hormonal artificial pancreas with both insulin and glucagon release.

Question 25

What are the four ways glucose control is measured?

Answer 25

Measuring Blood Glucose

• By knowing what blood glucose levels are you can adjust the insulin regime accordingly
• Measurements taken immediately prior to meals (breakfast lunch and dinner) and bed
• Its customary to take all four readings daily -> but some doctors mandate only two a day and alternate which readings are taken on each day.

HbA1c

• When glucose is high, it non-enzymatically glycosylates to proteins via irreversible covalent bonds
• Haemoglobin is glycosylated in this way - readings of HbA1c glycosylation give indirect measure of average blood glucose for preceding 3 month life span of Hb.
• Target HbA1c = 7% ; lower targets are associated with increased risk of hypoglycaemic attacks if base glucose levels are lower.
• Note: if there is normal HbA1c but hyperglycaemia, it indicated bleed loss from somewhere

Fructosamine

• measure glycosylation of serum albumin
• is conducted in patients with high RBC turnover with naturally low HbA1c levels

Assessment of Complications

• retina examination (yearly)
• measure of urinary albumin (yearly)
• examination of peripheral nerve sensation with microfilament

Question 26

How do you manage a hypoglycaemic emergency?

Answer 26

Hypoglycaemic emergency is defined as blood glucose < 4mmol/L caused by excessive insulin administration for a particular situation

There are two different sets of symptoms relating to:

Rapid rate of glucose fall

• ​triggers reflex sympathetic drive and adrenaline release
• causes tacchycardia, anxiety, dry mouth and tremor
• In older diabetic patients can trigger silent angina and result in myocardial infarction

Absolute glucose deficiency

• leads to brain malfunction and may cause paralysis, coma and if prolonged and sever enough death

TREATMENT:

• If the patient is conscious give oral glucose followed by a carbohydrate rich meal
• if the patient has diminished consciousness, give IV glucose or glucagon
• Investigate why hypoglycaemia occured

Question 27

How do you manage emergency ketoacidosis?

Answer 27

If a long standing type 1 diabetic is without adequate insulin for a day uncontrolled lipolysis and ketosis occurs

If severe the the keton bodies produced can cause ketoacidosis with a low blood pH

Precipitating causes:

• Infection
• Cessation of insulin
• New Onset Diabetes
• Pancreatitis
• Spontaneous

Presenting symptoms:

• Polyuria
• Polydipsia
• Weight loss
• Drowsiness
• Coma
• Ketouria

Management:

• Admission to hospital
• IV Saline
• Administration of insulin
• Replacement of potassium
• Investigate cause of ketoacidosis