Oral Agents for Diabetes Chapter 41 PDF

Summary

This document presents an overview of oral agents for diabetes, including their mechanism of action, common adverse effects, and contraindications. It details the regulation of blood glucose, hormone actions, and the progression to hyperglycemia. The presentation discusses various types of diabetes, treatment considerations, and monitoring parameters.

Full Transcript

Oral Agents for Diabetes
Chapter 41
Presented by
Susan Hartfield PA-C, PharmD
Overview

Review the regulation of blood glucose
Discuss hormone actions (insulin, glucagon)
Discuss the metabolic progression to hyperglycemia and diabetes
Review the screening and diagnosis of diabetes
Discuss treatment of hypoglycemia
Overview
Review the mechanism of action, common adverse effects,
contraindications, monitoring parameters and clinical pearls regarding the
following classes of drugs
Biguinides
Sulfonylurea’s
Meglitinides
Thiazolidinediones (TZD’s)
Alpha glucosidase inhibitors
Dipeptidyl peptidase inhibitiors (DPP-4 Inh)
Sodium-glucose co-transporter 2 (SGLT 2) inhibitors
 Objectives
Recognize, understand, and demonstrate knowledge of pancreatic and
gut hormones and antidiabetic drugs including:
Generic names
Pharmacokinetics and pharmacodynamics
Mechanism of action
Indications/contraindications
Adverse effects
Drug interactions
Regulation of Blood Glucose

▪ Pancreatic hormones
▪ Islet of Langerhans
Alpha cells - secrete glucagon which increases plasma glucose
Beta cells - secrete insulin and amylin
Delta cells - secrete somatostatin (GHIH)

▪ Small Intestinal L cell
Secrete peptide hormones called incretins
https://myendoconsult.com/learn/islet-cells-of-the-pancreas
▪ Glucagon-like peptide 1 (GLP-1): stimulates the beta cells to secrete more insulin
> Inhibits alpha cells from releasing glucagon, slows gastric emptying, promotes satiety
> Role is to attenuate large increase in plasma glucose that occurs with a meal
▪ Dipeptidylpeptidase 4 (DPP-4) - breaks down GLP-1
 Hormone Action
Insulin
Promotes the uptake, usage and storage of glucose (lowering glucose
plasma concentration)
Promotes formation of glycogen, TG and protein
Promotes the uptake of glucose by skeletal muscle and adipose tissue by
activating a glucose transporter called GLUT-4
Glucose provides energy for skeletal muscle contraction. Inhibits protein
catabolism.
In adipose tissue, glucose is converted to fatty acid and stored as triglyceride.
Hormone Action
Glucagon
Produced by the alpha cells of the pancreas
Made in response to low glucose concentration
Activates glycogenolysis and gluconeogenesis and increases hepatic glucose
production
Amylin
Secreted by the pancreatic beta cells along with insulin
Reduces the rate of rise of blood glucose
Slows gastric emptying
Suppresses glucagon secretion
Reduces appetite
Diabetes Mellitus

▪ Type I
Caused by autoimmune destruction of beta cells triggered by a viral infection or other environmental factor
Most common in children and adolescents
5-10% of all cases of DM
Insulin deficiency. Need life-long insulin treatment
Can have excessive production of ketones

▪ Type 2
Caused by insulin resistance/low insulin secretion
Most common type of DM
~90% of all cases of DM
Diabetes Mellitus
Secondary
MODY - maturity onset diabetes of the young
Cystic fibrosis
Pancreatectomy
Drug or chemical induced (such as prednisone)

Gestational
New onset diabetes diagnosed in the 2nd or 3rd trimester
Screening for Diabetes
Screening in Children
Diagnosis of Pre-Diabetes/Diabetes
 The Progression of Insulin Resistance
Modern life
Lifestyle choices - diet (glucose, fructose), sedentary, weight gain.  episodic insulin.
Initial stage of NAFLD. Labs are still “normal”

Hyperinsulinemia
Same lifestyle habits/diet/low exercise.
Fasting insulin progressively higher, fasting glucose is progressively lower
Hypoglycemic episodes
Stress hormones increase
More cravings
insulin resistance
The Progression of Insulin Resistance
Escalating Diabetes
Lifestyle habits sustain  blood glucose
Beta cell dysfunction, fasting insulin and response to meals is lower
 TG,  FFA, leptin resistance
 fat tissue and fatty liver
 tissue oxidative stress
 systemic inflammation
Presents with polyuria, polydipsia
 The Progression of Insulin Resistance

Metabolic Syndrome
BG, TG, HDL
Oxidative damage to endothelial lining of the arteries
Intracellular oxidative stress
Inflammation rises
 homocysteine
HTN worsens
Visceral abdominal obesity
 Major Contributors to Insulin Resistance
High glycemic diet
Processed food: Need Mg, biotin, calcium and chromium for healthy insulin sensitivity.
Essential Fatty Acid (EFA) deficiency: impairs cell membrane and insulin receptor sensitivity.
Lack of exercise: minimizes utilization of fuel,  insulin receptor sensitivity.
Age
Stress: Cortisol by itself raises insulin levels
Genetics
Medications: Steroids, diuretics (depletes Mg)
Consequences of Insulin Resistance
By driving down blood sugar we exacerbate the actual root cause.
Insulin levels are sustained
Promoting more insulin resistance
Increased body fat
Obesity
Higher free fatty acids
Worsening non-alcoholic fatty liver disease
Cancer
Oxidative stress
Correlation of SMBG and A1C
Treatment Considerations
Drug efficacy
A1c
Fasting plasma glucose (FPG)
Postprandial glucose (PPG)

Comorbidities (ASCVD, HF, CKD)
Cardiovascular benefits
Renal effects

Adverse effects
Hypoglycemia
Weight change
MOA
Oral or injectable
Cost
Goals of Therapy
Personalize goal(s) for each patient
Hemoglobin A1c
– For all patients with T2DM
– Goal: 48 hours following
▪ Best practice is to document adequate renal function before restarting but this is not always done.

▪ Boxed Warning:
May cause rare Lactic Acidosis
Serious/life-threatening

▪ Safe to use in pregnancy
Metformin

Obtain eGFR prior to starting metformin and at least annually in all patients
– Possibly more frequently in those at high risk for renal impairment (eg. elderly)

If eGFR falls to < 45 mL/min/1.73 m2
– May consider dosage reduction (50% dose reduction or 50% of maximal dose)
– Monitor renal function every 3 months

Starting therapy with an eGFR from 30 to 45 is not recommended
Contraindicated with eGFR 3x(ULN)
Weight gain
Edema/ heart failure symptoms
 Alpha-Glucosidase Inhibitors

▪ Agents: acarbose (Precose®) and miglitol (Glyset®)
▪ Mechanism: delay breakdown and absorption of complex carbohydrates
Alpha glucosidase is an enzyme on the brush border of the GIT
Does not increase insulin levels or cause hypoglycemia when used alone
Does not affect absorption of lactose, fructose or glucose

▪ Reduces post-prandial glucose
▪ Minimal to no oral absorption
▪ Acarbose
Initial 25mg with one meal/day
Titrate gradually to three times daily (max 300mg daily)
 Alpha-Glucosidase Inhibitors

▪ Adverse Effects:
GI: flatulence, bloating, abdominal discomfort, diarrhea

▪ Contraindications:
Short bowel syndrome, inflammatory bowel disease
SCr >2mg/dL
Cirrhosis
Colonic ulceration
Intestinal obstruction
 Alpha-Glucosidase Inhibitors

▪ Clinical Pearls
Take with first bite of meal
Only with meals containing complex carbohydrates
Decrease A1c by 0.7-0.8%
Titrate dose slowly to minimize GI effects
Must have glucose (dextrose) rather than sucrose (needs alpha glucosidase for breakdown)
source available to treat potential hypoglycemia if on an AGI
▪ Can use glucose tablets or gel, fructose (100% apple, orange or other fruit juice or milk
They do not cause lactose intolerance
 Alpha-Glucosidase Inhibitors

▪ Monitoring
A1C
Consider adding post meal SMBG for select patients
LFTs (can cause hepatitis)
SCr (avoid use with SCr >2)
Incretins
 Selective Dipeptidyl Peptidase-4 Inhibitors (DPP-4 Inhibitors)

▪ Medications-all end in “-gliptin”
Alogliptin (Nesina®)
Linagliptin (Tradjenta®)
Saxagliptin (Onglyza®)
Sitagliptin (Januvia®)
DPP-4 Inhibitors

▪ Mechanism:
↑ insulin secretion in response to elevated blood glucose
Decrease postprandial hyperglycemia in Type 2 DM
↑ sense of fullness and slows gastric emptying
Inhibit enzymes responsible for breaking down incretin hormones
▪ The two principal incretin hormones are glucagon-like peptide 1 (GLP-1) and glucose-dependent
insulinotropic peptide (GIP)
▪ Causes greater than 80% inhibition on DPP-resulting in a 2-fold increase in GLP-1 levels
 DPP-4 Inhibitors

Mechanism
▪ Basal levels of GLP-1 and GIP are low but increase rapidly after ingestion of food; they are
inactivated by the enzyme dipeptidyl-peptidase 4 (DPP-4)
▪ Both GLP-1 and GIP stimulate insulin secretion
▪ GLP-1 additionally stimulates insulin synthesis, inhibits glucagon secretion and reduces
gastro-intestinal motility
▪ The effects on insulin and glucagon secretion occur only when blood levels of glucose are
elevated, preserving the glucagon response to hypoglycemia.
 DPP-4 Inhibitors
▪ Adverse Effects:
Hypoglycemia (mild); low risk for serious hypoglycemia
Severe joint pain
▪ Warnings and precautions:
Increased risk HF
Acute pancreatitis
▪ Clinical Pearls:
Can be used as monotherapy
Decrease A1c by 0.5-0.7% - targets post prandial BG
Weight neutral
Can be used in combo with other agents
Available as a single tablet combined with metformin
 DPP-4 Inhibitors

▪ Monitoring
A1c
Renal function (dose may need adjustment)

▪ Reports of pancreatitis
▪ May increase the risk of cancer
Modulator of cellular invasion
Animal studies-promoted spread of existing tumor (liver/colon)
▪ Did not increase formation
 DPP-4 Inhibitors
Dipeptidyl peptidase-4 inhibitors and cancer risk in patients with type 2 diabetes: a meta-analysis of
randomized clinical trials
Found no increase in risk of cancer

Other papers show mixed results
DPP-4 can act as a tumor suppressor or activator.
Overall risk of cancer not increased however certain types of cancer were: bladder,
kidney, liver cancer, melanoma (see next slide); Colon, lung, prostate reduced.
Sodium-glucose co-transporter-2 (SGLT2) inhibitors -”Glifozins”

▪ Dapagliflozin (Farxiga®)
▪ Canagliflozin (Invokana®)
▪ Bexagliflozin (Brenzavvy®)
▪ Stoagliflozin (Inpefa®)
▪ Empagliflozin (Jardiance®)
Proven to reduce major CV events and CV mortality
Good choice for patients with ASCVD
Reduces the progression of renal disease in type II diabetics
SGLT2 Inhibitor Benefits
SGLT2 Inhibitors

▪ Mechanism
Blocks glucose reabsorption in the kidney
Increases of urinary glucose
Lowers renal threshold for glucose
▪ 180mg/dl
 SGLT2 Inhibitors
▪ Adverse effects:
Hypotension
Volume depletion/↑SCr and ↓eGFR (d/t osmotic effect of Na/glucose)
▪ AKI requiring dialysis (dapagliflozin and canagliflozin)
> More likely with dehydration, ACEI, diuretic, HF
Hyperkalemia
Hypoglycemia (if used with insulin or sulfonylurea)
Rash, hypersensitivity reactions
Increase the risk of UTI and genital mycotic infections (Fournier’s gangrene)
Decrease in BMD/fractures- urinary Ca loss (canagliflozin)
Increased risk of bladder cancer (dapagliflozin)
May be associated with acute pancreatitis
↑Risk of amputations (6 out of 1000-canagliflozin over 1 year compared to 3/1000 other DM meds)
 SGLT2 Inhibitors
▪ Clinical pearls
Weight loss or weight neutral
A1c (↓ ~0.7 %)
Contraindicated for patients with eGFR 70 mg/dL, eat a full meal
 Glucagon
Hormone released by alpha cells of pancreatic islets
Stimulates glycogen breakdown in the liver with release of
glucose
Restores plasma glucose toward normal
Onset in 5-20 minutes
Hyperglycemic action is short-lived
Glucose production decreases to the basal rate after about 60
minutes