Toxicology Lecture 4 PDF

Summary

This is a lecture on toxicology, covering various methods of enhancing the elimination of toxins, including forced diuresis, alkalinization and acidification of urine, extracorporeal techniques, and more. It discusses different types of antidotes, supportive treatments for various conditions, and potential complications. It is well-structured and clearly well-presented, with a use of diagrams.

Full Transcript

Toxicology
DR.MAMDOUH ORABY
 Introduction

Principles of
management of
toxicity
 Arsenic

5- Enhance elimination of the toxins
❑ Enhance elimination of the toxic agent from
the circulation should be done when the poison:
1) Is present at high concentration in plasma relative
to its concentration in the organs (small
distribution volume, Vd).
2) Is excreted in urine and its metabolite.
3) Dissociates rapidly from the plasma binding
proteins
4) Has low molecular weight and size
 Arsenic

5- Enhance elimination of the toxins
I- Forced diuresis:
▪ Enhance the excretion of drugs/metabolites through
the kidney.
✓N.B: Isn’t effective for chemicals that are reabsorbed
by renal tubules (Conc. of these chemicals is low in the
urine).
a. Diuretics
▪ Diuretics are used to increase the urine output.
▪ Ex: Mannitol & furosemide.
 Arsenic

5- Enhance elimination of the toxins
b. Alkalinization of urine:
❑ Promotes the excretion of weak acids
❑ Increases their ionization “ion trapping“ in the
renal tubules.
❑ Ex; Na bicarbonate & acetazolamide →
alkalinize the urine (pH = 7.5-8).
❑ Ex; Weak acidic drugs (ex; salicylates,
phenobarbitone, methotrexate) can be eliminated
by alkalinization of urine.
 Arsenic

5- Enhance elimination of the toxins
c. Acidification of urine
Promotes the excretion of weak bases
Increases their ionization “ion trapping “ in the
renal tubules.
Ex; Ammonium chloride & ascorbic acid →
acidify the urine (pH = 5.5-6).
Ex; Weak basic drugs (ex; amphetamine,
quinine, phencyclidine) can be eliminated by
acidification of urine.
 Arsenic

Enhance elimination of the toxins
II. Extracorporeal techniques:
❑ Dialysis is employed as an adjunct for the
management of severely intoxicated patients.
It is not necessary for toxins;
✓ Having specific antidotes; Ex: opioid toxicity
(specific antidote, naloxone).
✓ Very rapidly toxic agents; Ex; cyanide
(produces toxic effects within minutes).
 Arsenic

Enhance elimination of the toxins

❑ During dialysis,
Chemicals diffuses through
a semipermeable
membrane from higher
concentration area (blood
& interstitial fluids) to
lower concentration ones
(dialyzing solution).
 Arsenic

Enhance elimination of the toxins

a. Peritoneal dialysis:
▪ Patient’s peritoneum is used as in
vivo semipermeable membrane
▪ Fluids & dissolved chemicals are
exchanged from the blood into
dialysis fluid down its concentration
gradient through peritoneum.
 Arsenic

Enhance elimination of the toxins
❑ N.B: Adequate peritoneal blood flow is essential,
so it is inefficient in patients with hypotension.
❑ Composition of dialysis solution:
✓Sodium chloride & lactate & bicarbonate
✓High glucose concentration to make the dialysis
fluid hypertonic?
▪ N.B: For chemical toxins that are highly protein-
bound, albumin is added to the dialysis solution.
 Arsenic

Enhance elimination of the toxins
Complications:
❑ Abdominal pain
❑ Protein loss
❑ Intraperitoneal bleeding
❑ Water & electrolyte imbalance
❑ Intestinal, bladder, liver, spleen
perforation.
 Arsenic

Enhance elimination of the toxins
b. Hemodialysis:
▪ An in vitro
semipermeable
membrane (artificial
kidney) is used for
diffusion of chemicals
from blood to the
dialysis fluid.
 Arsenic

Enhance elimination of the toxins

❑Complications:
✓Infection
✓Hypotension
✓Bleeding & clotting
▪ N.B: Chemicals must have small
molecular size
❑ N.B: Hemodialysis is less effective for
highly protein-bound chemicals (can ҆t
pass through the semipermeable
membrane).
 Enhance elimination of the toxins
c. Hemoperfusion:
▪ The blood passes through a sterile column (or
cartridge) containing activated charcoal, ion
exchange resins to adsorb toxic chemicals from the
blood.
▪ N.B: Hemoperfusion is more effective than
peritoneal and hemodialysis?
Due to the greater surface area offered by
dialyzing membrane (column).
 Enhance elimination of the toxins
❑ Advantages: Suitable for detoxifying:
▪ Lipid soluble substances
▪ High protein-bound chemicals
❑ Complications:
✓ Trapping of WBCs & Platelets
✓ Activation of the clotting system
▪ These complications are overcome by using
newer adsorbent systems (such as charcoal +
acrylic hydrogel).
 Enhance elimination of the toxins
d. Plasmapheresis:
▪ A method for separating red blood
cells from the liquid plasma.
▪ RBCs are then mixed with a new
fresh frozen plasma or treated plasma
and returned to the body.
❑ Disadvantage:
✓ Some patient ҆s plasma proteins can be
lost.
 6- Antidote therapy
A. Chemical antidote:
❑ Chemical antidotes react with the poison chemically to
produce compounds with lower toxicity.
❑ Ex. 1: Calcium salts react with oxalic acid (causes
renal damage) → poorly soluble Ca2+ oxalate (can ҆t be
absorbed through the intestine).
❑ Ex. 2: Chelating agents (Ex; dimercaprol (BAL) &
deferoxamine & EDTA & penicillamine) react with
heavy metals → chemical chelates (water-soluble &
readily excreted in urine).
 6- Antidote therapy
B. Receptor antidote:
▪ The antidote antagonizes the receptor of the poison.
▪ Ex. 1: Naloxone (μ receptor antagonist) is an antidote for opioids
(ex; morphine)-induced respiratory depression.
▪ Ex. 2: Atropine (M-antagonist; has anticholinergic effects) is an
antidote for organophosphates-induced cholinergic toxidrome.
▪ Ex. 3: Physostigmine (cholinesterase inhibitor; ↑ Ach) is an
antidote for atropine toxicity
 6- Antidote therapy
C. Functional (physiologic) antagonism:
The antidote produces physiological effects that oppose
the effects of the poison.
❑ Ex 1: Epinephrine is used for severe anaphylactic
reactions following administration of a drug (induce
bronchodilation).
❑ Ex 2: Vitamin K (↑ synthesis of blood coagulation
factors) is used to treat the hemorrhage caused by
coumarin.
 6- Antidote therapy
D. Enzymatic antidote:
▪ Ex. 1: N-acetylcysteine acts as the endogenous GSH enzyme.
▪ Used to detoxify acetaminophen by forming a non-toxic intermediate
conjugate ( ↓ liver toxicity).
▪ Ex. 2: Pralidoxime is used to reactivate acetylcholinesterase enzyme
(breakdown of Ach) in case of organophosphorus toxicity.
▪ Ex. 3: Ethanol (10%) is used to detoxify methanol by reducing the
formation of formic acid by inhibiting alcohol dehydrogenase (saturation
of the enzyme).
 7- Supportive treatment
A. Hypertension:
Can cause cerebral hemorrhage & pulmonary edema.
Amphetamines & Cocaine & Corticosteroids can induce
hypertension.
❑ Treatment
1. Sodium nitroprusside: used for treatment of
hypertensive crises.
2. Other vasodilators: ex; Nitroglycerin & Ca+2 channel
blockers.
 7- Supportive treatment
B. Anaphylaxis:
▪ A serious reactions with a rapid onset that can lead to death.
❑ Causes:
✓ Insect bites and stings
✓ Certain types of food such as seafood.
✓ Medications (ex, penicillin, NSAIDs).
❑ Treatment:
1. Epinephrine & I.V fluids (for circulatory failure &
bronchospasm).
2. Antihistamines & Corticosteroids.
3. Bronchodilators
 Supportive treatment

C. Seizures:
❑ Seizures can be induced by various toxicants
(ex; organophosphorus compounds) & drug
abuse overdose (amphetamines & cocaine).
❑ Treatment:
1. Benzodiazepines ( ex; diazepam &
midazolam).
2. Phenytoin as an anticonvulsant.
 Supportive treatment
D. Electrolyte disturbances:
Hyperkalemia (serum K > 5.5 mEq/L)
❑ Causes:
ACE inhibitors (captopril) & ARBs (losartan)
❑ Treatment:
▪ I.V. Ca2+ gluconate, Na bicarbonate, diuretics (↑ K+
excretion).
▪ Polystyrene sulfonate Na+ or Ca+2 (exchange resin
in intestine)
 Supportive treatment
Hypokalemia: (serum K < 3.5 mEq/L)
✓ Causes: NSAIDs, Steroids, diuretics.
✓ Treatment: Oral or I.V. K+.
Hypernatremia (↑ Na+):
✓ Causes: NSAIDs & Corticosteroids
✓Treatment: Diuretics
Hyponatremia (↓ Na+):
✓ Causes: ex; desmopressin
✓ Treatment: hypertonic saline
 Supportive treatment
E. Hyperthermia:
❑ Severe hyperthermia (core temperature 42⁰C) is a devastating
condition that causes:
✓Brain damage
✓Coagulopathy (Bleeding)
✓Denaturation of the enzymes
✓Death
I. Malignant hyperthermia:
▪ Is a severe reaction to certain drugs used for anesthesia
▪ Ex; succinylcholine & general anesthetic gases such as halothane.
 Supportive treatment
❑ During anesthesia, Ca2+ is released in large
amounts muscles due to overstimulation of Ca2+
channels (ryanodine receptors) → Excessive
muscle contraction → Hyperthermia
❑ Complications
Severe muscle rigidity → Destruction of muscle
fibers (rhabdomyolysis)
↑ Metabolic rate → ATP depletion.
Muscle breakdown → ↑ myoglobin, K+,
creatine, phosphate into the blood → renal failure
 Supportive treatment

❑Treatment:
Dantrolene, a
ryanodine receptor
antagonist → ↓ Ca+2
release from the
sarcoplasmic reticulum
→ muscle relaxation.
 Supportive treatment
II. Exertional heat stroke:
▪ It is an excessive heat generation due to excessive
muscle activity.
❑ Cause:
✓ Drugs; Ex; amphetamine & cocaine & strychnine.
❑ Treatment:
✓ Anticonvulsant
✓ Neuromuscular blocker
✓ Evaporative cooling
 Supportive treatment
IV. Anticholinergic syndrome:
❑ Cause:
Agents: atropine & antihistamines → ↓ cholinergic (Ach)-
mediated sweating → hyperthermia
❑ Treatment:
▪ Evaporative cooling
▪ Physostigmine (cholinesterase inhibitor → ↑ Ach→ sweating)
Thank You