Systems Pharmacology and Chemotherapeutics PDF

Summary

These lecture notes cover Systems Pharmacology and Chemotherapeutics topics, including antihistamines, autacoids, prostaglandins, and histamine. The material presents a high-level overview of the key pharmacology concepts for these chemical mediators, including mechanisms of action, therapeutic uses, and adverse effects.

Full Transcript

Systems Pharmacology and
Chemotherapeutics
SCPCB3-B44

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Higher Education Act, 101, of 1997. Registration Certificate number: 2001/HE07/008
Antihistamines Lesson
1
Autacoids
Prostaglandins H1 Antihistamines H2 antihistamines

Mifepristone Acrivastine Cimetidine
Misoprostol Cetirizine Ranitidine
Chlorpheniramine
Cyclizine
Desloratidine
Diphenhydramine
Dimenhydrinate
Doxepin
Doxylamine
Fexofenadine
Hydroxyzine
Loratidine
Meclizine
Promethazine
H1 antihistamines
Antihistamine pharmacology

Antihistamine pharmacology

Visual Mnemonic

Visual Mnemonic
Introduction
Autocoids:
Prostaglandins
Histamine
Serotonin
Are all formed by the tissues upon which they act
Differ from local hormones as:
They are produced by many tissues
Rather than in specific endocrine glands
Prostaglandins
Prostaglandins
Abortion

Abortifacients
Oral administration: mifepristone followed by
Vaginal administration of misoprostol (24
hours later)
AE’s: infection, haemorrhage & retained tissue
Therapeutic uses
Peptic ulcers

Inhibit secretion of gastric acid
Also enhances mucosal resistance to injury in
patients with gastric ulcers using NSAIDs
Histamine
Anaphylaxis
“markedly improved susceptibility
to a specific protein after a suitable
incubation period”
-- Charles Richert, 1902

Current definition: sudden, severe, potentially fatal, systemic
allergic reaction that can involve various areas of the body (such as
the skin, respiratory tract, gastrointestinal tract, and cardiovascular
system).
Common cause: Food, Insect stings, Medicines, Latex
Histamine
NH2

5 4

1 3
N N
H Sir Henry Dale,
2 discovered histamine
Histamine
Experiments:
- Guinea pigs
- Dogs
Histamine
Location: Lungs, skin, GIT, ↑ [] in mast cells & basophils
Synthesis
Decarboxylation of the amino acid histidine
By histidine decarboxylase
Enzyme expressed by the following cells:
Neurons
Gastric mucosa parietal cells
Mast cells: histamine stored in granules
Inactive complex composed of histamine & heparin
If histamine is not stored, it is rapidly inactivated by enzymes
Basophils
Biosynthesis of histamine
Histamine
Release of histamine
Released in response to certain stimuli
In conjunction with other mediators
Stimuli examples:
Destruction of cells as a result of:
Bacterial toxins
Bee sting venoms
Trauma
Allergies
Anaphylaxis
Histamine
Mechanism of action
Histamine binds to: H1, H2, H3 & H4 receptors
H1 and H2 receptors: Widely expressed
Targets for certain drugs
H3 and H4 receptors: Expressed in only a few cell types
Histamine
Receptors
Contain seven transmembrane helical domains
G protein-mediated second messenger systems
H1 receptors
Smooth muscle contraction
Increasing capillary permeability
H2 receptors
Gastric acid secretion
Actions of
histamine
Role in allergy & anaphylaxis
IV histamine: produces actions similar to anaphylactic shock
Resulting from release of certain mediators from storage sites:
Histamine, serotonin, leukotrienes, eosinophilic chemotactic factor
Differences in severity:
Sites of release
Rates of release
Does it allow inactivation?
Actions
Contraction of smooth muscle
Stimulation of secretions
Dilation & increased permeability of the capillaries
Antihistamines
Actions of H1 antihistamines
Inhibition of release of mediators from mast
cells & basophils
Down-regulation of certain transcription
factors
Decreased production of pro-inflammatory
cytokines
Histamine H1
Receptor
Blockers
H1 Antihistamines
Mechanism of action
Does not inhibit formation or release of histamine!
Instead, it blocks receptor-mediated response of target tissue
Whereas cromolyn inhibits release of histamine from mast cells
First generation
Older
Inexpensive
Penetrate CNS: sedation
Interact with a variety of other receptors
Causing a variety of AE’s
Cholinergic, adrenergic or serotonin receptors
Low specificity
H1 Antihistamines
Second generation
Specific for H1 receptors
Do not penetrate BBB
Least sedation:
Desloratidine
Fexofenadine
Loratidine
Relative potential for sedation
H1 Antihistamines
Therapeutic uses:
Allergic and inflammatory conditions
Allergic rhinitis & urticaria
Ineffective in bronchial asthma
Systemic anaphylaxis: epinephrine

Motion sickness and nausea
Examples: diphenhydramine, dimenhydrinate, cyclizine,
meclizine, hydroxyzine
Independent of their antihistaminic actions

Somnifacients
Examples: diphenhydramine & doxylamine
Therapeutic advantages &
disadvantages of H blockers
1
Pharmacokinetics
Oral adminstration: well absorbed
Half life: 4-6 hours
Meclizine: longer t1/2 (12-24 hours)
More effective: prophylactically
Effects of H Antihistamines at
1

various receptors
Adverse effects
CNS effects
Sedation, tinnitis, dizziness, lassitude, incoordination, blurred vision,
tremors
Dry mouth
Anticholinergic effects
Drug interactions
Potentiation of the effects of other CNS depressants
Alcohol
May not be used together with MAOI’s: exacerbate anticholinergic
activity
Overdoses
Acute poisoning: CNS
Hallucinations, excitement, ataxia, convulsions, cardiorespiratory
collapse
Adverse effects
Histamine H2
Receptor
Blockers
H receptor blockers
2

Therapeutic use
Inhibitors of gastric acid secretion
In the treatment of ulcers
Mechanism of action:
Reduce intracellular levels of cAMP
Thereby reducing secretion of gastric acid
Examples:
Cimetidine, ranitidine, famotidine & nizatidine
 Immuno- Lesson
2

pharmacology
Organ transplant rejection
prevention
Induction drugs:
Powerful antirejection medicine used at the time of
transplant (just before)
Maintenance drugs:
Antirejection medications used for the long term
Rejection agents:
Medications which are used for the treatment for
rejection episodes
Immunosuppressive drugs

Selective inhibitors of cytokine Immunosuppressive
production & function antimetabolites
Cyclosporine Azathioprine
Everolimus Mycophenolate mofetil
Sirolimus Mycophenolate sodium
Tacrolimus
Antibodies Adrenocorticoids
Alemtuzumab Methylprednisolone
Antithymocyte globulins Prednisolone
Basiliximab Prednisone
Dacilzumab
Muromonab-CD3
Introduction
Earlier immunosuppressants
Non-selective
Suppression of both parts of the immune system
Humoral
Cell-mediated
Introduction
Rx
Autoimmune diseases
Organ & tissue transplantation

Severely toxic drugs
Used in combination
At low doses
Selective Inhibitors of
Cytokine Function &
Production
CD (clusters of differentiation)
Ability to act as receptors

Expressed by lymphocytes and antigen presenting cells
Antigen presenting cells:
CD80
CD86
T Cells:

CD3
CD28
CD25 (IL receptor)
Mechanism of action:
Cyclosporine- CsA (IV or PO)
CsA diffuses into T Thus nFATc cannot And cytokines are
cells enter the nucleus not produced

No IL-2 to stimulate
Binds to cyclophilin But now calcineurin proliferation of T
(a immunophilin) to cannot perform this cells or activate NK
form a complex function cells, macrophages
& cytotoxic T cells

Calcineurin (a type CYP3A4
of phosphatase)
This complex binds Extensive drug interactions
function:
to calcineurin
dephosphorylates
nFATc
Cyclosporine (CsA)
Cyclic peptide
Extracted from a soil fungus
More effective when administered with a glucocorticoid
Rx:
Prevention of organ transplant rejection
RA: alternative to methotrexate
Psoriasis
Mechanism of action
Preferentially suppresses cell-mediated immunity
Effect of cyclosporine on liver
transplant survival
Adverse effects: Cyclosporine
Nephrotoxicity
Avoid coadministration of drugs that can cause kidney
dysfunction:
E.g. Aminoglycosides, anti-inflammatories (diclofenac,
naproxen), cimetidine
Hepatotoxicity
Development of life-threatening infections
Herpes & cytomegalovirus
Lymphoma
Adverse effects: Cyclosporine
Anaphylactic reactions on parenteral administration
Hypertension
Hyperkalemia
Do not use potassium sparing diuretics
Tremor, Hirsutism, Gum hyperplasia
Tacrolimus (TAC)
Rx:
Rejection of liver & kidney transplants
Given in conjunction with a glucocorticoids
Preferred over cyclosporine
Less episodes of rejection
More potent
Lower doses of glucocorticoid necessary?
Mechanism of action
Similar to cyclosporine
Binds to a different immunophilin
FKBP-12
Mechanism of action: Cyclosporine
& Tacrolimus
Tacrolimus
Pharmacokinetics
IV or oral
Absorption decreased when taken with high fat meals
Potency: 10 – 100 times more potent than CsA
Highly plasma protein bound
Concentrated in erythrocytes (like CsA)
Interpersonal variation: oral absorption incomplete & variable
Requires dosage adjustment
CYP3A4
Extensive drug interactions
Tacrolimus
Adverse effects
More severe than CsA
Nephrotoxicity
Neurotoxicity
Tremors
Seizures
Hallucinations
Development of insulin-dependent Diabetes mellitus
Black & hispanic patients
Anaphylaxis
Does not cause Gingival hyperplasia or Hirsutism
Five year renal allograft
survival in patients treated with
tacrolimus or cyclosporine
Sirolimus (SRL)
Macrolide
From fermentations of a soil fungus
Equipotent to CsA
Rx:
After renal transplantation
In conjunction with glucocorticoids & CsA (synergism)
Sirolimus coated stents in cardiac vasculature
Antiproliferative effect : reduces proliferation of endothelial cells
Prevents restenosis
 Mechanism of action:
Sirolimus
SRL binds to FK-BP
But does not form a complex with
calcineurin
Instead SRL binds to mTOR =
mammalian target of rapamycin
mTOR function: cell cycle progression,
DNA repair, protein translation
Thus by binding to mTOR, T cells
arrest in the G1 phase
Sirolimus
Pharmacokinetics
High fat meals decrease SRL’s absorption
Highly plasma protein bound
Metabolism: CYP3A4
Same drug interactions as CsA & TAC
Elimination: faeces
Its immunosuppression lasts 6 months after cessation of therapy
Adverse effects: Sirolimus
Combination of CsA & SRL is more nephrotoxic
(Combination of TAC & SRL is less toxic)
Hyperlipidaemia
Headache
Nausea
Diarrhoea
Hypertension
Leukopaenia & thrombocytopaenia
Immunosuppressive
Antimetabolites
Used in combination with CsA, TAC &
glucocorticoids
Azathioprine
Azathioprine is
converted to 6- Thus require de
mercaptopurine novo synthesis
(6-MP)

6-MP is converted Majorly affects
to thioinosinic lymphocytes: lack
acid (nucleotide purine salvage
analogue) pathway

Thioinosinic acid
Lymphocytes
=
(rapidly dividing)
immunosuppressi
require PURINES!
ve
Mechanism of action: Azathioprine
Azathioprine
Pharmacokinetics
Erratic absorption from oral route
Does not cross the BBB
Decrease the dose of azathioprine in
Hyperuricaemic patients receiving allopurinol
Azathioprine
Adverse effects
Bone marrow suppression
Nausea & vomiting
Mutagenic and carcinogenic
Concomittant use with ACE-I’s or cotrimoxazole
In renal transplant patients
> leukopaenic response
Mycophenolate mofetil
Replacing azathioprine
Rx:
Heart, liver & kidney transplants
Pharmacokinetics
Mycophenolate mofetill & mycophenolic acid are both highly plasma
protein bound
Coadministration with the following drugs decreases absorption:
Magnesium/aluminium antacids
Cholestyramine
 Mechanism of
action:
Mycophenolate
Mycophenolate
mofetil is rapidly Thus T & B cells
hydrolysed to cannot synthesize
mycophenolic acid nucleic acids
(MPA)

Causes inhibition
Blocking the de
of ionosine
novo synthesis of
monophosphate
guanosine
dehydrogenase
phosphate (GP)
(IMPDH)
Mycophenolate mofetil
Adverse effects
Pain
Diarrhoea
Leukopaenia
Opportunistic infections
Lymphoma
Sepsis
MPA is less mutagenic & carcinogenic than
azathioprine
Antibodies
Immunization of rabbits & horses
With lymphoid cells
Producing polyclonal antibodies
Hybridoma technology
Fusing mouse Ab-producing cells with
Immortal, malignant plasma cells
Producing monoclonal antibodies
Recombinant DNA technology
Humanizing mouse genes
Naming conventions: monoclonal
antibodies (-mab)
Antithymocyte globulins
Thymocytes: T-cell precursors
Polyclonal antibodies
Rx:
Hyperacute phase of allograft rejection
Antithymocyte globulins bind to T-cells
Which are destroyed by:
Complement-mediated destruction
Antibody-dependent cytotoxicity
Apoptosis
Opsonization
Antibody-bound T-cells are phagocytosed in the liver & spleen
Result: lymphopaenia & impaired T-cell responses
Antithymocyte globulins
Does not affect the humoral part of the immune system
So antibodies can still be formed against foreign antigens
Adverse effects
Chills & fever
Leukopaenia & thrombocytopaenia
Anaphylaxis
Skin rashes
infections
Muromonab-CD3 (OKT3)
Therapeutic applications:
Acute rejection of renal allografts
Steroid-resistant acute allograft rejection
In cardiac & hepatic transplant patients
Deplete T cells from donor bone marrow prior to transplantation
Mechanism of action
Muromonab-CD3 binds to CD3 protein (monoclonal)
This blocks the access of the antigen to the recognition site
Which disrupts T-cell function
Which depletes T-cells
Which decreases the immune response
Muromonab-CD3
Pharmacokinetics
IV
Extensive metabolism
First administration: cytokine storm
Premedication: methylprednisolone,
diphenhydramine & acetaminophen
Adverse effects: Muromonab-CD3
Anaphylactic reactions

Cytokine storm symptoms

Ranges from a mild flu-like illness to a life-threatening, shock-like
reaction
High fever
CNS effects: seizures, encephalopathy, cerebral oedema, aseptic
meningitis, headache

Contraindications

Pregnant & breastfeeding women
Heart failure patients
Seizure patients
IL-2 receptor antagonists
Humanised antibody = Daclizumab
90% human protein
Chimerized antibody = mBasiliximab
25% mouse & 75% human protein
Therapeutic applications
Prophylaxis of acute rejection in renal transplantation
Used in conjunction with CsA & corticosteroids
IL-2 receptor antagonists
Mechanism of action:
Bind to the IL-2 receptor
Thus interfering with the proliferation of T-cells
Also prevents antigens from activating the T-cell immune response
Basiliximab is 10x more potent than daclizumab
Pharmacokinetics
IV
Daclizumab > t1/2
Adverse effects
Both are well tolerated
GIT effects
Glucocorticoids
Adrenocorticoids
Transplantation
Prednisone & methylprednisolone
Used in combination with other immunosuppressants
Autoimmune conditions
E.g. RA, SLE
Prednisone & prednisolone
Mechanism of action:
Reduce T-cell populations
Mechanism of action
Glucocorticosteroids bind to intracellular
cytoplasmic receptors in target tissues

Dimerise and then the receptor-hormone
complex translocates to the nucleus

Where it attaches to gene promotor
elements

Acts as a transcription factor to turn genes
off (in all macrophage-like/immune cells)

Produces effects
 AEs:
Long term
corticosteroid therapy
 Anti- Lesson
3

Hypertensives
Introduction
Systolic: >140mmHg
Diastolic: > 90mmHg
Can lead to:
Myocardial infarctions
Congestive heart failure
Renal damage
Cerebrovascular incidents
Frequency of
concomitant
diseases in
hypertensive
patients
Introduction
Joint National Committee on prevention, detection,
evaluation and treatment of high blood pressure
Classifies hypertension
Risk factors
Stressful lifestyle
High dietary intake of sodium
Obesity
Smoking
Introduction
Aetiology of hypertension
Essential hypertension
More common form of hypertension
Black people more prone to hypertension than whites
Males are more prone than females
Secondary hypertension
Caused due to other diseases
Antihypertensive drugs
Is it B1 B2 receptors that play a role is vasoconstriction of arteriole
smooth muscle? or
Angiotensin II
Diuretics β-blocker ACE Inhibitors receptor
antagonist
Amiloride Atenolol Benazepril Azilsartan
Bumetanide Carvedilol Captopril medoxomil
Chlorthalidone Labetalol Enalapril Candesartan
Eplerenone Metoprolol Fosinopril Eprosartan
Furosemide Nadolol Lisinopril Irbesartan
Hydrochlorothi Nebivolol Moexipril Losartan
azide Propranolol Quinapril Olmesartan
Metolazone Timolol Ramipril Telmisartan
Spironolactone Valsartan
Triamterene
Antihypertensive drugs
Sodium nitroprusside- a derivative of nitric oxide, which acts as a?

Calcium channel
α-blockers Renin inhibitors Other
blockers

Amlodipine Doxazosin Aliskiren Clonidine
Diltiazem Prazosin Diazoxide
Felodipine Terazosin Hydralazine
Isradipine α-methyldopa
Nicardipine Minoxidil
Nifedipine Sodium
Nisoldipine nitroprusside
Verapamil
You will be asked the
following:
What are the target(s) for the following three drugs:

1)Ramipril
2)Losartan
3)Hydrochlorothiazide
Major factors affecting blood
pressure

What effect does binding of epinephrine to A1 receptors in
arteriolar smooth muscle have?
Mechanisms for controlling blood
pressure
Short term control

Sympathetic nervous system
Baroreceptors in the aortic arch & carotid
sinuses

Long term control

Renin-angiotensin-aldosterone system
Baroreceptors in the kidney
Treatment strategies
Reduce cardiovascular and renal morbidity & mortality
First line therapy:
Thiazide diuretics
Inadequately controlled hypertension
Add a β-blocker
If still uncontrolled
Add a vasodilator
Individualised treatment
Different patients respond better to certain drugs
Black patients:
Respond well to diuretics & CCB’s
Respond less effectively to β-blockers & ACE-I’s
Elderly patients:
Favoured: CCB’s, ACE-I’s, diuretics
Less effective: β-blockers & α-antagonists
Patient‘s comorbidities may be aggravated by
antihypertensive drugs
Patient compliance
Lack of compliance: main reason for failure of therapy
Asymptomatic patients
Diagnosed before complications
Adverse effects
E.g. β-blockers decrease libido & can induce impotence
Poor compliance
Not “worth it” to experience AE’s NOW to prevent diseases in the
FUTURE
Careful consideration of drug class for individual patients thus necessary!
Thiazide
Diuretics
Thiazide diuretics
First line treatment
Useful in combination therapy
Actions:
Short-term: increases water & sodium excretion
Which decrease plasma volume
Which decreases CO & renal blood flow
Long-term: plasma volume approaches normal,
But peripheral vascular resistance is decreased
Spironolactone can be administered simultaneously
Potassium-sparing diuretic
NB: Prevents heart remodelling
Actions of thiazide diuretics
Thiazide diuretics
Pharmacokinetics
Oral administration
Ineffective in patients with poor kidney function
Creatinine clearance = 150mmHg & SBP > 210mmHg OR
DBP >130mmHg in an individual with pre-existing complications:
Encephalopathy
Cerebral haemorrhage
Sodium nitroprusside
Aortic stenosis
Labetalol

Fenoldopam

Nicardipine
Hypertensive emergency treatments:
Sodium nitroprusside
IV administration
Rapidly metabolised
Requires constant infusion
Prompt vasodilation
Arteries: decreases BP
Veins: decreases preload
Adverse effects:
Cyanide toxicity
Due to production of cyanide ions
Administration of sodium thiosulphate
Produces thiocyanate
Hypertensive emergency treatments
Labetalol
IV
α and β blocker
Does not cause reflex tachycardia
Long t1/2
Fenoldopam
IV
Dopamine 1 receptor agonist
Increases renal perfusion: renal insufficiency
Nicardipine
IV
Calcium channel blocker
Comparison