Week 9 - Medications In Metabolic Disease PDF

Summary

This document provides an overview of medications used in the treatment of metabolic diseases, detailing various classes like biguanides, sulfonylureas, and more. It also touches upon the effects of exercise on these medications.

Full Transcript

WEEK 9: MEDICATIONS IN METABOLIC DISEASE

EHR522: EXERCISE FOR METABOLIC AND MENTAL HEALTH CONDITIONS

Subject Coordinator: Tim Miller
[email protected]
02 6338 4442
ORAL GLUCOSE-LOWERING MEDICATIONS
BIGUANIDES

 Metformin
 Fortamet
 Glumetza
 Glucophage

 Primarily decrease hepatic glucose production
 May also improve insulin resistance in muscles
 Very low risk of hypoglycaemia (possibly after
prolonged strenuous exercise)
 Not used in patients with abnormal creatinine
clearance (CHF and CKD)
SULFONYLUREAS (1ST GENERATION)

 Rarely used in current clinical practice. Examples
include
 Tolbutamide (Orinase)
 Tolazamide (Tolinase)
 Chlorpropamide (Diabenese)

 Increase insulin production in the pancreas
 Carry a significant risk of hypoglycaemia
 Many have a very long half-life and are typically
now only used in patients with a well-established
history of taking them
SULFONYLUREAS (2ND GENERATION)

 Examples include
 Glyburide (Micronase, Diabeta, Glynase)
 Glipizide (Glucotrol, Glucotrol XL)
 Glimepiride (Amaryl)

 Increase insulin production in the pancreas
 Carry a risk of hypoglycaemia (but less than that
of 1st generation sulfonylureas)
 2nd generation sulfonylureas provide more
predictable results with fewer side effects and
more convenient dosing when compared with 1st
generation sulfonylureas
THIAZOLIDINEDIONES

 Examples include
 Pioglitazone (Actos)
 Rosiglitazone (Avandia, Avandamet, Avandaryl)

 Works via multiple mechanisms
 Decrease insulin resistance, increasing glucose uptake
 Redistribution of fat
 Minor decrease in hepatic glucose output
 Preserve beta cell function
 Decrease vascular inflammation

 No significant risks with exercise, but can cause
mild to moderate oedema
ALPHA-GLUCOSIDASE INHIBITORS

 Examples include
 Acarbose (Precose)
 Miglitol (Glyset)

 Slows the absorption of starch, disaccharides and
polysaccharides from the GI tract
 No significant risks with exercise, but can cause
gas, bloating and occasionally diarrhoea
DIPEPTIDYL PEPTIDASE 4 (DPP-4) INHIBITORS

 Examples include
 Sitagliptin (Januvia)
 Saxagliptin (Onglyza)
 Vildagliptin (Glavus)
 Linagliptin (Tradjenta)

 Inhibits the DPP-4 enzyme that is responsible for
degrading the incretins, glucagon-like peptide-1
(GLP-1) and gastric inhibitory polypeptide (GIP)
 The increasing incretin levels inhibit glucagon
release, which in turn increases insulin secretion
and decreases BGLs
DIPEPTIDYL PEPTIDASE 4 (DPP-4) INHIBITORS

 DPP-4 inhibitors carry a low risk of
hypoglycaemia with exercise
 DPP-4 inhibitors are not used in T1DM
SODIUM-GLUCOSE CO-TRANSPORTER 2 (SGLT2) INHIBITORS

 Also known as gliflozins, examples include
 Canagliflozin (Invokana)
 Dapaglifozin (Farxiga)
 Empagliflozin (Jardiance)
 Erugliflozin (Steglatro)

 Inhibit the reabsorption of glucose in the kidneys,
therefore lowering BGLs
 Can increase the risk of ketoacidosis and UTI
 Can cause dehydration, so ensure patients are
well-hydrated with exercise
INJECTED (NON-INSULIN) MEDICATIONS
GLUCAGON-LIKE PEPTIDE-1 (GLP-1) RECEPTOR AGONISTS

 Examples include
 Exenatide (Byetta)
 Dulaglutide (Trulicity)
 Liraglutide (Victoza)
 Semaglutide (Ozempic)
 Lixisenatide (Adlyxin)

 Works via multiple mechanisms
 Decreases post-meal glucagon production
 Delays gastric emptying
 Increase satiety, leading to decreased caloric intake
GLUCAGON-LIKE PEPTIDE-1 (GLP-1) RECEPTOR AGONISTS

 Not suitable for T1DM
 May reduce the rate of absorption of oral
medications
 Can increase the risk of hypoglycaemia when
combined with a sulfonylurea
AMYLIN ANALOGUE

 Pramlintide (Symlin)
 Amylin is a peptide hormone that is co-secreted
with insulin from the pancreatic beta cells and is
therefore deficient in diabetics
 Works via multiple mechanisms
 Decreases post-meal glucagon production
 Delays gastric emptying
 Increase satiety, leading to decreased caloric intake

 The degree of response is dependent upon
plasma glucose levels
AMYLIN ANALOGUE

 Indicated for insulin-treated T2DM and T1DM
 Contraindicated in patients with hypoglycaemia
unawareness
 Should not be mixed with insulin (must be
injected separately)
 Can increase the risk of hypoglycaemia when
combined with insulin. Insulin dose is typically
reduced by 50% when initiating treatment with an
amylin analogue
RAPID ACTING INSULIN
RAPID ACTING INSULIN

Do not allow patients to exercise at the peak
insulin dose of a rapid acting insulin (first 2
hours following drug administration)
SHORT ACTING INSULIN
INTERMEDIATE ACTING INSULIN
LONG ACTING AND ULTRA LONG ACTING INSULIN
NON-DIABETES MEDICATIONS
OVERWEIGHT AND OBESITY - PHARMACOTHERAPY
STATINS - EFFECTS OF GRAPEFRUIT

 The chemicals in grapefruit do not interact directly
with statin medications. Rather these chemicals bind
to an intestinal enzyme, blocking its action and
making the passage of the medication easier from
gut to bloodstream
 As a result, blood medication levels may rise faster
and remain at higher than normal levels, and in some
cases abnormally high levels are dangerous
 Regarding statins and grapefruit use, some statins are
affected more than others. For example, atorvastatin
(Lipitor), simvastatin (Zocor) and lovastatin
(Mevacor), blood levels are boosted more than when
fluvastatin (Lescol), pravastatin (Pravachol) or
rosuvastatin (Crestor) is the prescribed medication.
 As a recommendation, any grapefruit product should
be avoided when taking a statin
LIPID-LOWERING MEDICATIONS
LIPID-LOWERING MEDICATIONS
LIPID-LOWERING MEDICATIONS

 A longstanding limitation for niacin has been that it is
not well tolerated, although extended-release forms
have improved tolerance
 Niacin therapy often results in flushing, skin rashes,
gastrointestinal problems and pruritus
 Niacin is not recommended for individuals with
hypotension, liver dysfunction or peptic ulcers or for
those with diabetes mellitus, as it often causes
increases in blood glucose concentrations
 You should remind patients to take niacin before
going to sleep at night to avoid these unwanted side
effects during the day and especially with exercise
 You should also make patients aware of these side
effects to distinguish between the effect of the drug
and what might be experienced during exercise
LIPID-LOWERING MEDICATIONS

 Up to 25% of patients taking lipid-lowering
medications, particularly statins and fibric acid
derivatives, may experience some form of
medication intolerance that includes muscle
inflammation or muscle damage
 Rhabdomyolysis – A severe side effect arising
from medication-induced muscle damage, is
characterised by the presence of myoglobin in the
blood, reduced and dark urine output and a
general feeling of weakness.
 Since kidney damage may result, a patient
experiencing these symptoms should immediately
contact their Physician
PCOS – PHARMACEUTICAL INTERVENTION

 Pharmaceutical treatment for PCOS focuses
primarily on addressing reproductive dysfunction
and insulin resistance
 Oral contraceptives are used to treat menstrual
irregularity, hirsutism and acne. Long-term use of
oral contraceptives, however, remain controversial
from a cardiometabolic standpoint
 Spironolactone (aldosterone antagonist) and
finasteride (5-alpha reductase inhibitor) are used
to treat symptoms of androgen excess