DIABETES MELLITUS _FS 2024_Part I.pdf

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DIABETES

DR. J. SAVORY
 Université d’Ottawa | University of Ottawa

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 Pre-lecture Review (Self learning)

You’ll need a good understanding of metabolism and pancreatic
function to tackle diabetes. You may want to take some time to
review either:
the relevant chapters in the you Anatomy and Physiology text
▪ Chapter 16 - Pancreatic function
▪ Chapter 24 - Metabolism

Slides with this symbol will be discussed VERY briefly
during the lecture because the information on these slides would
have been covered in your ANP courses and it will be assumed
that you have taken the time to review the information on your
own if you need a refresher.
 OBJECTIVES
1. Review: briefly summarize the metabolic processes that take place during
absorptive and post absorptive states and their hormonal regulation
2. Describe the cellular composition of the islets of Langerhans; identify the cells
responsible for the synthesis of insulin and glucagon
3. Glycemic control
3.1. Summarize the regulation of the synthesis of insulin and glucagon; give
examples of physiological conditions that can increase or decrease the
secretion of each hormone.
3.2. Identify the target tissues of insulin and glucagon.
3.3. Summarize the mechanisms of insulin and glucagon action and describe the
metabolic effects of insulin and glucagon on carbohydrate, lipid and protein
metabolism.
3.4. Identify and briefly describe the neural mechanisms and hormones that can
support the effects of glucagon.
3.5. Define: glucose sparing
 OBJECTIVES CONTINUED
4.1. Define: 'diabetes mellitus’
4.2. Describe screening for diabetes mellitus using the fasting plasma glucose test, oral
glucose tolerance test, the concentration of glycosylated hemoglobin and the
presence of antibodies.
4.2.1. Distinguishing between the primary and secondary diabetes mellitus
4.2.2. Distinguish between type 1 and type 2 diabetes mellitus with respect to the causes, risk
factors, pathogenesis, and main characteristics.
4.2.3. Define gestational diabetes mellitus and explain its causes and the consequences for the
mother and her fetus.

4.3. List and describe the three classic signs of diabetes mellitus.
4.4. Define and identify the signs and symptoms of hyperglycemia and hypoglycemia and
their treatment; explain physiological causes of the Somogyi effect and the Dawn
phenomenon.
4.5. Compare and contrast the three acute complications of diabetes mellitus: (1) diabetic
ketoacidosis, (2) hyperosmolar coma, and (3) reactions to insulin, according to the
causes, clinical signs, metabolic changes, and treatment.
4.6. Describe the chronic effects of diabetes mellitus on the vascular, renal, visual, and
nervous systems.
4.7. Summarize the treatment of diabetes mellitus type 1 and type 2 and discuss lifestyle
modification and pharmacological strategies for treatment of type 2.
Chapter 41
 METABOLISM
All the chemical reactions that occur within the cells of the body
▪ includes reactions involving the degradation, synthesis, and
transformation of proteins, carbohydrates, and fats

Energy requirements met by carbohydrate (CHO), fats and
proteins >> Glucose (body’s fuel)
Amount is tightly regulated
▪ Too much- hyperglycemia
▪ Too little- hypoglycemia
GLUCOSE HOMEOSTASIS
 THE PANCREAS

The hormonal control of blood glucose resides largely
with the endocrine pancreas
▪ Retroperitoneal gland with both exocrine (80%) and endocrine
functions
▪ Head and neck opens into the C-shaped part of the duodenum

◼ The exocrine part composed of
the acini  secrete digestive
juices into duodenum via
special ducts

◼ The endocrine part composed of
the islets of Langerhans (~2
million)  secrete insulin,
glucagon and other hormones
directly to blood
https://jigsaw.vitalsource.com/books/9780323088541/content/image/9780323088541_0515.jpg
 ISLETS OF LANGERHANS

▪ Beta (b) cells ( 60%) produce
proinsulin.
▪ Stored in granules, where it is
cleaved into insulin and C-peptide
that are secreted together
▪ Alpha (a) cells (25%) produce &
secrete glucagon into the blood.

▪ Delta (d) cells (10%) produce
somatostatin (inhibits insulin and
glucagon)
Physiological anatomy of an islet
▪ F cells produce pancreatic of Langerhans in the pancreas
polypeptide (PP) Guyton & Hall, 2016

Insulin and glucagon are most important in regulating
fuel metabolism
 STRUCTURE OF INSULIN

◼ Insulin is a polypeptide hormone,
produced and stored in the body
as an inactive hexamer
◼ Monomeric form: composed of
two chains A (21 aa) and B (30
aa) linked by disulfide bridges
◼ BOTH chains are derived from
proinsulin, a prohormone.
◼ Active insulin and the inactive C-
peptide are packaged into
secretory granules and released
simultaneously from the b cells
◼ Insulin from human, cows and
pig are very similar
 FIG. 41.1 PROCESSES OF GLUCOSE-STIMULATED
EXOCYTOSIS OF INSULIN FROM ΒETA CELLS OF
THE PANCREAS

Amylin
Inhibits gastric emptying
Suppress glucagon release
 GLUCOSE AND INSULIN RELEASE
Under normal circumstances insulin
secretion occurs in 2 phases:
1st Phase (rapidly releasable pool)
The post prandial  in blood glucose & the
incretin hormones (GIP & GLP) produce
the first phase
within 3-5 min of  blood glucose, [insulin]
in plasma  almost 10x Release of
preformed insulin
2nd Phase (extended)
at ~ 15 min; insulin secretion rises a
second time and reaches a new plateau in
2-3 hours
↑ synthesis and release of new insulin from b-
cells

▪ In type 2 diabetes, even though lots of insulin is produced, the first phase
is lost  this has a major effect on insulin action
▪ With time – second phase also decreases
 FACTORS THAT REGULATE INSULIN SECRETION

GIP
GLP-1

Note:
GIP: glucose-dependent
insulinotropic polypeptide
GLP-1: glucagon-like peptide 1

Incretins are inactivated by the
enzyme dipeptidyl peptidase IV
(DPP-IV)
 FACTORS THAT REGULATE INSULIN SECRETION

Counter-regulatory hormones
Growth Hormone 

Stress hormones:
Glucocorticoids (Cortisol)  (↑ production of glucose in the liver,
stimulate glucagon release, & decrease glucose use)

▪ E/NE: ↑ production of FFAs & inhibit peripheral glucose uptake
▪ All these events lead to stress hyperglycemia
▪ Can also occur with psychological stress

Exercise
▪ Initially insulin levels ; glucagon & catecholamine levels , increasing
production of FFAs & stimulating glycogenolysis →→ glucose from liver
meets energy demands
▪ Muscle contractions increase insulin sensitivity, maintaining normal blood
glucose levels in the presence of lower insulin levels
 INSULIN ACTIONS

LIVER
Anabolic hormone Primary role in maintaining normal
Promotes cellular uptake of blood glucose levels
glucose, fatty acids, & amino Principal site for metabolic
acid; enhances their interconversions e.g. gluconeogenesis
conversion into glycogen,
triglycerides, & proteins, ADIPOSE TISSUE
respectively Primary energy storage site
Lowers blood concentration of
Important in regulating fatty acid levels
these small organic molecules in the blood

Secretion is increased during MUSCLE
absorptive state Primary site of amino acid storage
Major energy user

BRAIN
▪ Normally can only use glucose as an energy source
▪ Does not store glycogen / mandatory blood glucose levels
must be maintained
 GLUCAGON SECRETION & ACTIONS

▪ Major stimulus for glucagon Liver
release is  in blood [glucose]. increased hepatic glucose
▪ Amino acids stimulate production & release → an
glucagon release (high protein, increase in blood glucose levels
low carbohydrate meal).
Adipose
▪ Activation of the sympathetic NS antagonizes the actions of insulin
▪ Stress: epinephrine acts on b- with regard to fat metabolism by
adrenergic receptors on alpha promoting lipolysis & inhibiting
cells, increasing glucagon TG synthesis
release ( availability of
glucose for energy) Protein
inhibits hepatic protein synthesis
▪ Other counter regulatory and promotes degradation of
hormones (GH, cortisol) hepatic protein
INSULIN ACTION: SIGNAL TRANSDUCTION

Glucose Glycogen Protein Lipid Growth & gene
Transport Synthesis Synthesis Synthesis Expression
 INSULIN REGULATION OF GLUCOSE TRANSPORT

▪ Diffusion of glucose into cells is controlled by glucose
transporters (GLUT 1- 4) specific to each tissue
▪ GLUT 1-3 are insulin independent

Tissue Transporter
Blood Brain Barrier GLUT 1

Neurons GLUT 3 predominantly

Liver GLUT 2

Pancreatic b cells GLUT 1 & 3, small amounts of
GLUT 2

Muscle & Adipose
GLUT 4
tissue

▪ GLUT 4: normally located in
the cell’s cytoplasm
preformed and packaged into
vesicles.
 INSULIN RECEPTOR INTERNALIZATION

▪ Insulin binds to its
receptor & insulin-
receptor complex enters
cell via endocytosis
▪ Receptors are recycled
to the cell surface
▪ Insulin is largely
degraded in lysosomes

What would be the effect of having a
super high concentration of insulin?
ENERGY METABOLISM IN THE FED AND FASTING STATES

FIG. 41.4 Energy metabolism in FIG. 41.5 Energy metabolism in the
the fed (absorptive) state. fasting (post-absorptive) state.

[Glucose]
[Glucose]

G, Glucose
FFA, Free fatty acid(s)
 DIABETES MELLITUS (DM)
Glucose intolerance disorder
▪ is a chronic condition characterized by elevated blood
glucose levels (hyperglycemia).

A group of multisystem metabolic diseases resulting from
▪ defects in insulin production
▪ impaired insulin action
▪ both of the above

▪ disturbances of CHO, FAT and PRO metabolism
▪ variety of organic changes resulting primarily from blood
vessel pathology
▪ Leading cause of heart disease, stroke, adult blindness,
and non-traumatic lower limb amputations

22
 TYPES OF DIABETES MELLITUS

DIABETES MELLITUS (DM)

Pre- Other types of DM
Primary DM Gestational DM
Diabetes (Secondary DM)

Pancreatic
Type 1 DM Type 2 DM Diseases
Endocrinopathies Drug Induced

Type 1A Type 1B Cushing’s Glucose
(idiopathic) Acromegaly
(autoimmune) Syndrome Hypersecretion

Polygenic Monogenic LADA
(80-90% of cases) (very rare) Latent Autoimmune Diabetes in
Adults
(2-12%; typically diagnosed after
age 35 )
TYPE 1 DIABETES MELLITUS (T1 DM)

https://www.ndss.com.au/wp-content/uploads/images/type1-diabetes.png
 TYPE 1 DIABETES MELLITUS (T1 DM)
Usually diagnosed between 5 and 20 years of age
Characterized by destruction of the β cells of the pancreas
Etiology may be immune-mediated or idiopathic (without autoimmune markers or HLA
association)
 Results in absolute insulin deficiency
 Overproduction of glucagon stimulates glycogenolysis and gluconeogenesis
 Glucose levels rise leading to the clinical phenotype of T1 DM

[Glucose]

FIG. 41.7 Pathophysiology of energy metabolism in type 1 diabetes mellitus. FFA, Free fatty acid(s); G, glucose; KA, ketoacid(s).
 PATHOPHYSIOLOGY OF TYPE 1A
IMMUNE MEDIATED DM

McCance and Huether's Pathophysiology: The Biologic Basis for Disease in Adults and Children
 TYPE 1A: IMMUNE MEDIATED DM
GENETIC PREDISPOSITION ENVIRONMENTAL FACTORS
INHERITED SUSCEPTIBILITY DIABETOGENIC VIRUSES
Strongest linkage Infection of beta-cells (e.g.
polymorphism of human leucocyte cytomegalovirus - CMV)
antigen (HLA) genes in the MHC (provides Systemic infection with cross-reacting
~50% of the susceptibility that leads to immune response
type 1 DM) – mumps, chickenpox, coxsackie B,
95% Type 1 diabetics carry HLA-(DR3 – measles, rubella
DQ2) / (DR4-DQ8)
other weaker links found (~60) DIETARY FACTORS (early weaning in
infants)?
SEROLOGICAL Cow milk proteins in formula (TRIGR-
compare protein to hydrolysate – no
Type 1 diabetes associated with the
difference) https://www.trigr.org/
following autoantibodies Decreased vitamin D (decreased
Insulin Auto Antibodies (IAA) exposure to the sun)
Glutamic acid decarboxylase (GADA)
zinc transporter 8 (ZnT8A)
Insulinoma-associated autoantigen 2 MICROBIOTA
(IA2A) Alterations to gut bacterial population
and production of metabolites may
impact autoimmunity

27
 MODEL OF STAGES OF TYPE 1 DM

J Clin Invest. 2021;131(8):e142242. https://doi.org/10.1172/JCI142242.
Date of Download: 8/25/2024 Copyright © 2024 American Diabetes Association. All rights reserved.
 DIAGNOSIS OF DIABETES
Normoglycemic IFG§ IOGT§ DM
TEST (mM) (mM) (mM) (mM)

FPG < 5.6 5.6 – 6.9 7.0

Symptoms of hyperglycemia and a
casual plasma glucose ≥11.1 mM. The
classic symptoms of hyperglycemia
include polyuria, polydipsia, and
unexplained weight loss.

2 h-OGTT < 7.8 7.8 - 11.0 > 11.1

HbA1C 4% - 5.6% 5.7% - 6.4% > 6.5%

Clinical diagnosis rely on two main features
presence of islet-directed autoantibodies
insulin deficiency and the need for insulin therapy

FPG is defined as no caloric intake for 8 hours
OGTT with 2-hour measurement of venous plasma or serum glucose after a 75-g oral glucose load
IFG – impaired fasting glucose IGT- impaired glucose tolerance
HbA1C –hemoglobin A1C § these are considered pre-diabetic states
Type 1 diabetes mellitus: much progress, many opportunities

J Clin Invest DOI: 10.1172/JCI142242
 HONEYMOON PERIOD

Short period after diagnosis during which
the ability of the failing b cells become
hyper-productive and compensate for
failing insulin response. During this time
Symptoms of diabetes disappear
Insulin injections are reduced or not
needed

31
 TYPE 2 DIABETES MELLITUS
▪ Most common form of DM (90 – 95%)
▪ Non-Caucasian and elderly
disproportionately affected Possible causes of b cell failure
▪ Insulin resistance and β cell
dysfunction lead to a relative lack of
insulin
Suspect decreased number of
insulin receptors or abnormal
translocation of glucose transporters
As disease progresses, insulin
production may be impaired
▪ increased plasma insulin concentration
(hyperinsulinemia) – a compensatory
response to insulin resistance

b cell dysfunction / dedifferentiation
rather than b-cell death and decrease in
b-cell mass
Information about type 2 DM in Canada
https://www.diabetes.ca/DiabetesCanadaWebsite/media/Managing-My-Diabetes/Tools%20and%20Resources/type-2-diabetes-the-basics.pdf?ext=.pdf
RISK FACTORS FOR TYPE 2 DIABETES
▪ Age: being 40 years of or older
▪ Family history: having a close relative (parent/ sibling) with type 2 DM
▪ Being a member of a high-risk population, such as those of African, Arab, Asian,
Hispanic, Indigenous or South Asian descent,

▪ Hypertension: high blood pressure or cholesterol
▪ Obesity: being overweight, especially around your abdomen.
▪ Level of physical activity
▪ Stress (hypothalamic-pituitary- adrenal axis: 
cortisol/catecholamines)
▪ Socio-economic factors: low education / unemployment
▪ Having obstructive sleep apnea
▪ Low socioeconomic status
▪ Having a history of prediabetes (IGT or IFGT) / a history of gestational diabetes
▪ Having a history of giving birth to a baby that weighed over 4 kg (9 lb) at birth
▪ Having some evidence of the complications of diabetes, such as eye, nerve or
kidney problems
▪ Having heart disease
▪ Having a history of using glucocorticoid medication
 METABOLIC SYNDROME AND TYPE 2 DM

Also known as insulin resistance syndrome is a cluster of
conditions that occur together, increasing your risk of type 2
diabetes (as well as cardiovascular disease and stroke)

▪ central obesity,
▪ Dyslipidemia (↑ TG, ↓ HDL)
▪ Hypertension,
▪ elevated fasting blood
glucose level (impaired
glucose tolerance)

https://relatyv.com/wp-content/uploads/2023/05/metabolic-syndrome-illustration.webp
PATHOPHYSIOLOGY OF TYPE 2 M

McCance and Huether's Pathophysiology: The Biologic Basis for Disease in Adults and Children
 [Glucose]

Insulin Resistance

↑FFA

FIG. 41.8 Pathophysiology of energy metabolism
in type 2 diabetes mellitus. G, Glucose.