Reorientation training programme

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Title: Reorientation training programme

1
Re-orientation training programme
WELCOME

SIGNIFICANCE OF TOXICOLOGY
FOR
HOMOEOPATHIC PHARMACOLOGY

2
Dr. Srinath Rao B.H.M.S., M.D (Hom)

VICE PRINCIPAL
HEAD OF DEPARTMENT
DEPT. OF HOMOEOPATHIC MATERIA MEDICA
FR. MULLER HOMOEOPATHIC MEDICAL
COLLEGE HOSPITAL
DERLAKATTE, MANGALORE

3
PHARMACOLOGY

The science or study of drugs
their preparation and properties
(origin,nature,chemistry)
and
uses and effects.

4
The word Pharmacology

Greek pharmakon meaning drug, and logos,
knowledge".
Early pharmacologists focused on natural
substances, mainly plant extracts.
Pharmacology developed in the 19th century as a
new biomedical science that applied the
principles of scientific experimentation to
therapeutic contexts.

Pharmacology deals with all aspects of the
actions of drugs on living tissues, particularly
their effects on man.
Drugs' actions, both at the molecular level
(interaction of drug molecules with receptors)
and also at the macroscopic or whole-body level
(such as drug effects on the cardiovascular
system), are considered.
The subject can be divided into two main
sections pharmacodynamics and pharmacokinetics.
The first is concerned with how the effects of a
drug are generated, while the second is concerned
with how drugs are distributed around the body,
how they are metabolized, and how they are
finally excreted or eliminated from the body.
Discovery of new drugs proceeds by considering
how chemical agents can be used to potentiate,
inhibit, or modify some cellular or bodily
process.

6
Subdisciplines

Clinical Pharmacology - the medical field of
medication effects on humans
Neuro and Psychopharmacology - effects of
medication on behavior and nervous system
functioning
Pharmacogenetics - clinical testing of genetic
variation that gives rise to differing response
to drugs
Pharmacogenomics - application of genomic
technologies to new drug discovery and further
characterization of older drugs
Pharmacoepidemiology - study of effects of drugs
in large numbers of people
Toxicology - study of the effects of poisons
Theoretical Pharmacology
Posology - how medicines are dosed
Pharmacognosy - deriving medicines from plants

7
Pharmacodynamics

Pharmacodynamics is the study of the biochemical
and physiological effects of drugs on the body or
on microorganisms or parasites within or on the
body and the mechanisms of drug action and the
relationship between drug concentration and
effect

8
Pharmacokinetics

Greek "pharmacon" meaning drug and "kinetikos"
meaning putting in motion, the study of time
dependency)
Pharmacokinetics is a branch of pharmacology
dedicated to the determination of the fate of
substances administered externally to a living
organism. In practice, this discipline is applied
mainly to drug substances, though in principle it
concerns itself with all manner of compounds
ingested or otherwise delivered externally to an
organism, such as nutrients, metabolites,
hormones, toxins, etc.
Pharmacokinetics is often divided into several
areas including, but not limited to, the extent
and rate of Absorption, Distribution, Metabolism
and Excretion.

9
PHARMACOLOGY

The discipline of pharmacology is the study of
the effects of drugs on living organisms where a
drug can be broadly defined as any chemical
substance, natural or synthetic, which affects a
biological system.
Pharmacology may involve how organisms handle
drugs, mechanism of drug action, drug toxicity,
the use of drugs as probes to delineate
biological processes during health and disease,
identification of new targets for drug action,
and the design and development of new drugs.
These investigations can occur at the molecular,
subcellular, cellular, tissue or whole organism
level.
Pharmacology is an interdisciplinary science
employing experimental approaches which may
include biochemistry, physiology, immunology,
molecular biology, genetics and cell biology.

10
TOXICOLOGY

Greek words toxicos and logos is the study of the
adverse effects of chemicals on living organisms.
It is the branch of medical science, which deals
with poisons with special reference to their
source, character, properties, symptoms they
produce, and of remedial measures.

11
Pharmacology Toxicology

Pharmacology is the study of the actions and uses
of therapeutic agents in the treatment of
diseases.
Toxicology is the study of the poisonous or
harmful effects of drugs and chemical agents.

Pharmacologists, emphasizing the mechanisms by
which drugs act, draw on the disciplines of
physiology, pathology, biochemistry, biology, and
microbiology to examine the actions of chemicals
on living organisms.
Toxicologists are engaged in the investigation of
poisons, or toxins, from the standpoint of
detection, isolation, identification, and
determination of their effects on the human body.
Pharmacologists and toxicologists work together
as part of a multidisciplinary team, which may
include synthetic chemists, cell and molecular
biologists, clinicians, and experts in other
related disciplines.

13
Dose Toxicity

Toxicology is the study of the relationship
between dose and its effects on the living
organism.
The chief criterion regarding the toxicity of a
chemical is the dose, i.e. the amount of exposure
to the substance.
Almost all substances are toxic under the right
conditions as Paracelsus, the father of modern
toxicology said, Sola dosis facit venenum (only
dose makes the poison). Paracelsus, who lived in
the 16th century, was the first person to explain
the dose-response relationship of toxic
substances.

Even a benign substance like water can cause harm
in excessive amounts. "Dr. Adrian Cohen was
saddened, but not surprised, to hear about the
28-year-old woman who died earlier this month
after drinking nearly two gallons of water to try
to win a radio station contest."
Toxicology is also known as science of poisons.
There is evidence that early in the history of
the human race people understood the potency of
certain natural materials and used them in
hunting and for their therapeutic values.
Some familiar images from the past reinforce this
belief.For example,the story of Socrates
ingesting poison hemlock and the stereotype of
the royal starters are in this tradition.
As time went on, and especially following the
scientific revolution,the understanding of how
chemicals affect the human body fell into the
domain of pharmacology.
Both beneficial and adverse effects were studied
under this general heading, and so toxicology was
but a branch or subset of pharmacology.

15
General aspects of poisoning

Duties of doctor in cases of poisoning
Medico-legal autopsy in poisoning
Preservation and dispatch of viscera for chemical
analysis
Role of Forensic Science Laboratory in brief

16
Types of poisons, diagnosis, principles of
therapy and medicolegal aspects of

Corrosive poisons strong mineral acids and
organic acids.
Metallic poisons Lead, Arsenic, Mercury and
Copper.
Animal poisons Snake and scorpion bites.
Deliriants Dhatura, Cannabis and Cocaine.
Somniferous agents Opium, Morphine and other
opiods
Inebriants Methyl and ethyl alcohol.
Asphyxiant poisons Carbon monoxide, Carbon
dioxide,
Methane and cyanides.

Anesthetic agents.
Cardiac poisons Cerebra thevetia and Nerium
odorum.
Miscellaneous Aspirin, paracetamol,
barbiturates, diazepam, antihistaminics,
antidepressants and kerosene oil.
Insecticides Organophosphorus compounds,
Carbamates and Organochloro compounds.
Food poisoning.
Drug abuse and dependence.

18
Desirable to know following poisonings

Inorganic non metallic poisons Phosphorous.
Organic vegetable irritants Abrus precatorious,
Capsicum, Calotropis, Semicarpus anacardium,
Croton.
Cardiac Poisons Aconite,
Convulsants Strychnine.
Paralytic agents, Curare.
War gases and Industrial gases.
Chloral hydrate.
Mechanical poisons.

19
FORENSIC MEDICINE AND MEDICAL JURISPRUDENCE
INCLUDING TOXICOLOGY

Goal
The broad goal of teaching undergraduate students
Forensic Medicine is to produce a physician who
is well informed about Medico-legal
responsibility during his/her practice of
Medicine.
He/She will also be capable of making
observations and inferring conclusions by logical
deductions to set enquiries on the right track in
criminal matters and associated medico-legal
problems.
He/She acquires knowledge of law in relation to
Medical practice, Medical negligence and respect
for codes of Medical ethics.

Educational objectives(a) Knowledge
i. Identify the basic Medico-legal aspects of
hospital and general practice
ii. Define the Medico-legal responsibilities of a
general physician while rendering community
service either in a rural primary health centre
or an urban health centre
iii. Appreciate the physicians responsibilities
in criminal matters and respect for the codes of
Medical ethics
iv. Diagnose, manage and identify also legal
aspect of common acute and chronic poisonings
v. Describe the Medico-legal aspects and findings
of post-mortem examination in cases of death due
to common unnatural conditions and poisonings
vi. Detect occupational and environmental
poisoning, prevention and epidemiology of common
poisoning and their legal aspects particularly
pertaining to Workmens Compensation Act
vii. Describe the general principles of
analytical toxicology

(b) Skills
i. Make observations and logical inferences in
order to initiate enquiries in criminal matters
and Medico-legal problemsa. to be able to carry
on proper Medico-legal examination and
documentation/Reporting of Injury and Ageb. to
be able to conduct examination for
intoxicationc. to be able to preserve relevant
ancillary materials for medico - legal
examinationd. to be able to identify important
post-mortem findings in common unnatural deaths
ii. Diagnose and treat common emergencies in
poisoning and chronic toxicity
iii. Make observations and interpret findings at
post-mortem examination
iv. Observe the principles of medical ethics in
the practice of his profession

22
CLASSIFICATION OF POISONS

Corrosives
Strong acids
Mineral or inorganic acids Sulphuric, Nitric,
Hydrochloric.
Organic acids Carbolic, Oxalic, Acetic,
Salicylic.
Strong alkalies
Hydrates and Carbonates of sodium,
Potassium and Ammonia.
Metallic Salts
Zinc chloride , Ferric chloride , Copper sulphate
, Silver nitrate , Potassium cyanide , Chromates
and Bichromates.

Irritants
Agricultural
Inorganic
Non metallic Phosphorus, iodine, chlorine,
bromine, carbontetrachloride.
Metallic Arsenic, antimony, copper, lead,
mercury, silver, zinc.
Mechanical Powered glass, diamond, dust, hair,
etc.
Organic
Vegatable Abrus precatorius, castor, croton,
calotropis, aloes.
Animal Snake and insect venom, cantharides,
ptomaine.

Systemic
Cerebral
CNS depressants Alcohols, General Anaesthetics,
Opioid Analgesics , Hypnotics, Sedatives.
CNS stimulants Cyclic Antidepressants,
Amphetamine, Methylphenidate, Caffine.
Deliriant Datura, Belladonna, Hyoscyamus,
Cannabis, Cocaine, etc.
Spinal Nux vomica , Gelsemium .
Peripheral Conium , Curare .
Cardiovascular Aconite , Quinine , Oleander ,
Tobacco , Hydrocyanic Acid, Digitalis
Asphyxiants CO, CO2, Hydrogen Sulphide.

25
Oxalic Acid

Its prepared from pine saw dust by oxidizing
with caustic alkali.
They are white shiny crystals, which are
strongly acidic and sour in taste.

Uses -
To clean glass and metals
For manufacturing straw hat
For floor polishing
For removing ink stain

Fatal dose
15 gm
Fatal period
3-10 minutes
Mode of action
Locally as corrosive
Systemic precipitation of ionized calcium from
the body.

Signs and symptoms
Immediate intense sour taste in mouth
Burning pain in mouth, throat, stomach
Retching, nausea, vomiting (Coffee ground
appearance due to altered blood in vomitus
till death.
Oliguria and anuria.

During 1st 2 days
Excess of albumin in urine
Crystals of oxalate, hyaline casts in urine
Hypocalcaemia tetany, convulsion, lock
jaw, severe prostration with cold, clammy
sweaty limbs, hurried respiration.
COMA
DEATH

PM findings
Signs of corrosion in mouth, throat, oesophagus
and stomach.
Whitish mucous membrane turns greyish
Blackish from altered blood
Submucosal haemorrhages
Submucosal blood vessels appear like
black net work
Shiny crystals of oxalic acid can be seen in
mucous membrane.

Ammomia (NH3)
Solution of ammomia is known as spirits of
Harts Horn a colourless strongly alkaline
pungent liquid.
Uses
As chemical
As bleaching agents
In medicines

Action
Irritation of skin and corrodes mucous membrane
produces soft necrotic areas on contact with
tissues.
Action is slow but long sustained.
Intense stimulation of alkalis on absorption may
cause reflex loss of vascular tone and cardiac
inhibition.

Fatal Period
Inhalation of ammonia vapour may cause death
within 4 minutes from edema glottis and death
within 1 week or more due to bronchopnenumonia.

Signs and symptoms
Burning
Mouth, throat, abdomen
Acrid nauseous taste in mouth
Excoriation and ulceration of mucous membrane
Vomiting -vomitus contain altered blood
Liquid stool containing blood and mucus
Dysphagia and dyspnoea.
Skin burned cold clammy
Abdominal pain tender on pressure
Pulse quick, weak, feeble.
Eyes shrunken, pupils dilated
Shock, collapse and death.

Treatment
Neutralize with weak vegetable acids along with
water.
Demulcent milk, lemon, barely, white of egg.
Stomach wash and emetic should not be tried
causes perforation

Postmortem changes
Marks of corrosion over lips, mouth, tongue,
esophagus.
Deep chocolate or dark brown discoloration
Edema and inflammation of parts
Stomach congested, blackish brown in colour dark
shiny fluid present
Sub-mucosal haemorrhage
All visceras congested

37
OPHIDIA

Poisonous
Elapid secreting neurotoxic venom.
Vipers Vasculotoxic
Sea snake- myotoxic
Non Poisonous

38
Elapid

Cobra
King Cobra
Common krait.
Banded krait.
Coral.

39
Characteristics Of Snake Venom

In the fresh state it is a clear transparent
amber tinted fluid and dries in to a yellow
granular mass which retains its activity for many
years. It contains toxalbumines and several
toxic principles such as the followings .
Fibrinolysins
Proteolysin
Neurotoxins prominent in elapid
venom
Cholinesterase

40
s

5. Haemolysin prominent in Viper venom
6.Thromboplastin
7. Agglutinns
8. Cardiotoxins
9.Coagulase, Hyaluronidase, lecithinase, etc
Elapid Neurotoxin
Viper Venom- Vasculotoxin
Sea snake - Myotoxin

41
Elapid- Neurotoxic Venom

It causes muscular weakness of the legs and
paralysis of the muscles of the face, throat and
respiration.
Neurotoxin of cobra venom produces both
convulsion and paralysis.
Krait venom cause only muscular paralysis.
Local symptoms at the site of the bite are
minimum as compared to caused by vasculotoxic
venom.

42
Viper Venom -Vasculotoxic

Its produces enzymatic destruction of cell wall
and coagulations disorder. As a result the
endothelium of blood vessels is destroyed, red
cell are lysed and other tissue cells are
destroyed.
There is oozing of Hemolytic blood and spreading
cellulitis.
Hemorrhages from external orifices of the body
are common.
Other functional disturbances are related to the
involved organs.. e.g.. Convulsion from
Hemorrhage on the brain

43
myotoxic Venom- Sea snake

Produces generalized muscular pain followed by
myoglobinuria 3 or 4 hrs later, ending of
respiratory failure in fatal cases
Toxic dose.

44
Signs and Symptoms..

Poisoning may occur from bite (injection) or
absorption of venom through cuts or scratches
(sucking).
In some cases instant death may occur from shock
due to fright.

45
Degree of toxicity depends on.

The size of the person bitten.
The potency of venom.
The main toxic principle it contains.
The amount injected which in turn depends up on
the age, size, sex and species of the snake
whether it had recently taken a prey, whether the
bite is on bare skin or through clothing.
Season and time of bite.
The type of fang whether canalized grooved.
Nocturnal bites may be more severs than those
occur during the day..

Bite From A Elapid Snake
Burning pain at the site of the bite which is
followed by.
Giddiness
Lethargy
Muscular weakness
Spreading Paralysis
Salivation.
Vomiting
Weakness in the legs is manifested by
staggering
Difficulty in speaking and swallowing.
Ptosis and paralysis of extra cellular
muscle may occur.
Breathing became slow and labored .
Conscious but unable to speak.
Respiratory causes with or with out
convulsion and heart stops.

Bite From Viper
Sever local symptoms and marked vascular toxic
effects.
Pain , swelling, ecchymosis and sever oozing of
Hemolytic blood.
Serous and serosanguinous blister sometimes
appears.
Nausea and vomiting occur..
Intra vascular Haemolysis may leads to
hemoglobinuric nephritis.
Petechial hemorrhage.
Bleedings from gums, Haemoptysis, bleeding from
the mucus membrane of the rectum and other
orifices of the body are common.
Collapse set in with clammy skin, rapid feeble
pulse and dilated pupil, insensitive to light,
followed coma and death.

A Bite From A Sea Snake
Felt as a sharp initial prick, becoming painless
later.
1-2 hrs after- generalized muscular pain and
stiffness develops.
Starting in the neck and limb gradually
Myoglobinuria causes a characteristic brown
colour urine.
Serum transaminase become elevated.
Hyperkalamia resulting from leakage of cellular
potassium following extensive muscle damage..
Respiratory failure may occur.

49
Venom And Fatal Dose

Amount of venom injected at a bite
200-350mg
150-200mg
22mg
4.5mg

venom Fatal Dose
Cobra 15mg
Viper -- 40mg
Krait -- 6mg
Echin carinata 8mg
(sea snake)

50
Fatal period

Cobra few mints to hours..
Viper few hours to days
Sea snake bite is merely not fatal.
However sudden death may be due to fright

51
Treatment of snake bite

Principle
To avoid the anxiety and fear.
Prevention of the spread of venom (First Aid).
Use of specific anti venoms.
General measures

52
SCORPIONS

Poisonous Principle
Toxalbumen which is haemolytic or neurotoxic.
ITS TOXICITY IS WORSE THAN THAT OF THE SNAKES,
BUT ONLY A SMALL QUANTITY IS INJECTED.

53
BEES AND WASPS

The poisonous principles contain complex mixture
of biochemical compounds ranging from simple
amines to complicated proteins and enzymes.
Histamines.
Attacks lasts for 24 hours.
Anaphylactic reaction occurs immediately or
within 20 minutes.
Death may occur in 2-15 minutes.

54
OPIUM

Opium is valued for the alkaloids it contains,
the total alkaloid content varying from 5-25. A
large number of alkaloids have been isolated from
opium-
Morphine
Codeine
Thebane
Narcotine
Narcine
Papaverine

The Morphine content of opium is maximum at the
first lancing and then rapidly decreases in
successive lancings.
SEEDS ARE FREE FROM ALKALOIDS.
Narcotine is said to be the first alkaloid to
appear three days after sprouting.

Opium alkaloids
The characteristic action of principal opium
alkaloids is their simultaneous depressing and
exciting effect on the CNS. The order of action
increases-morphine, papavarine, codeine,
narcotine and thebane.
Morphine is a powerful analgesic and narcotic and
also has stimulant action. It especially
depresses the thalamus, sensory cortex,
respiratory and cough centres. It stimulates the
spinal cord, the vagus and vomiting centres and
the third nerve centre.
It increases the tone of involuntary muscles,
specially in the sphincters of the alimentary
tract.

Codeine
Resembles morphine in its general effects but is
less narcotic. It stimulates not only the spinal
cord, but also the lower parts of the brain.
Papavarine
Acts chiefly as a relaxant of involuntary muscles
and has no marked narcotic or analgesic action.
It relaxes the muscles of the intestinal and
biliary tracts, bronchial tree, ureter and blood
vessels including coronary supply.

Narcotine
It is the most abundant of alkaloids after
morphine and has a very mild narcotic effect.
It has a colchicine like effect.

59
LEAD

Toxic dose
10 gm/70kg for most lead salts.
100mg/kg for tetraethyl lead.
Chronic lead poisoning is called PLUMBISM or
SATURNISM

60
Toxicological symptoms

Mild toxicity
(BL 40-60mg/100ml)
Myalgia.
Paraesthesia
Fatigue
Irritability
Abd discomfort

Moderate
(BL 60-100mg/100ml)
Arthralgia
Musular exhaustability
Tremor
Headache
Diffuse abd pain
Anorexia
Vomiting
Constipation
Weight loss

Severe toxicity
(BL More than 100mg/100ml)
Lead palsyWrist or foot drop.
Burtons lineA bluish black lead lines on gums.
Lead colicSevere abd cramps, tenderness around
umbilicus.
Lead encephalopathy Sudden onset of vomiting,
irritability, headache, ataxia, vertigo,
convulsions, psychotic manifestations, coma
death.
Facial pallor, esp circum oral characteristic
feature of c/c lead poisoning.

62
(No Transcript)
63
Lead poisoning - Gum Changes
64
Chronic lead poisoning- wrist drop
65
Pharmacological action

Loss of appetite, emaciation, pallor,
constipation.
Slowing of heart action.
Bilateral paralysis of extensor muscles of
forearm.
Blue or slate coloured lines appear at the edge
of gums.
Coliky, sharp abd. pain.
Calibre of small blood vessels contracted,
resulting in delirium,convulsions.
Albuminuria,Cirrhosis contraction of kidneys.
Amblyopia amaurosis.

66
ANTIDOTE

An antidote is a substance which can counteract a
form of poisoning .
Sometimes, the antidote for a particular toxin is
manufactured by injecting the toxin into an
animal in small doses and the resulting
antibodies are extracted from the animals' blood.
The venom produced by some snakes, spiders, and
other venomous animals is often treatable by the
use of these antivenins, although a number do
lack one, and a bite or sting from such an animal
often results in death.
Some animal venoms, especially those produced by
arthropods (e.g. certain spiders, scorpions,
bees, etc.) are only potentially lethal when they
provoke allergic reactions and induce
anaphylactic shock as such, there is no
"antidote" for these venoms because it is not a
form of poisoning, though anaphylactic shock can
be treated (e.g., by the use of epinephrine).

67
ANTIDOTE

Some other toxins have no known antidote. For
example, the poison ricin, which is produced from
the waste byproduct of castor oil manufacture,
has no antidote, and as a result is often fatal
if it enters the human body in sufficient
quantities.
Ingested poisons are frequently treated by the
oral administration of activated charcoal, which
absorbs the poison, and then it is flushed from
the digestive tract, removing a large part of the
toxin.
Poisons which are injected into the body (such as
those from bites or stings from venomous animals)
are usually treated by the use of a constriction
band which limits the flow of lymph and/or blood
to the area, thus slowing circulation of the
poison around the body.

68
POISONS THEIR ANTIDOTES

Anticholinergic poisoning is given physostigmine
sulfate as the antidote.
Atropine sulfatepoisoning is given
Anticholinesteraseand pralidoxime chloride 2-PAM
as the antidote.
Benzodiazepine poisoning is given flumazenil as
the antidote.
Beta blocker poisoning is given glucagon as the
antidote.
Carbon monoxide poisoning is given oxygen as the
antidote.
Cyanide poisoning is given amyl nitrite, sodium
nitrite, and thiosulfate as the antidote. A new
patented process uses mesoxalic acid as the
antidote.

69
POISONS THEIR ANTIDOTES

Digoxin poisoning is given Fragment antigen
binding(Fab) fragments that bind to digoxin
(trade names Digibind and Digifab) as the
antidote.
Ethylene glycol poisoning is given ethanol or
fomepizole as the antidote.
Extrapyramidal reactions associated with
antipsychotic poisoning is given diphenhydramine
hydrochloride and benztropine mesylate as the
antidote.
Heavy metal poisoning is given chelators, calcium
disodium edetate (EDTA), dimercaprol (BAL),
penicillamine, and 2,3-dimercaptosuccinic acid
(DMSA, succimer) as the antidote.
Heparin poisoning is given protamine sulfate as
the antidote.
Iron poisoning is given deferoxamine mesylate as
the antidote.

70
POISONS THEIR ANTIDOTES

Isoniazid poisoning is given pyridoxine as the
antidote.
Methanol poisoning is given ethanol or fomepizole
as the antidote.
Methemoglobinemia poisoning is given methylene
blue as the antidote.
Opioid poisoning is given naloxone hydrochloride
as the antidote.
Paracetamol (acetaminophen) poisoning is given
N-acetylcysteine as the antidote.
Thallium poisoning is given Prussian blue as the
antidote.
Warfarin poisoning is given vitamin K
phytonadione and fresh frozen plasma as the
antidote.

71
Administration of Antidotes

1) Mechanical or Physical antidotes They
neutralise poisons by mechanical action or
prevent their absorption.
Activated charcoal acts mechanically by
adsorbing and retaining within its poresorganic ,
and also to less degree mineral poisons , and
thus delays the absorption from the stomach.
Demulcents are substances which form a protective
coating on gastric mucous membrane and thus do
not permit the poisons to cause any damage ,eg
milk,starch, egg-white, mineral oil, milk of
magnesia , aluminium hydroxide gel.Fats and oils
should not be used for oil soluble poisons ,
such as kerosene, phosphorus , organophosphorus
compounds , DDT ,phenol, turpentine , aniline ,
acetone , carbontetrachloride etc.
Bulky food acts as a mechanical antidote to glass
powder by imprisoning its particles within its
meshes , and thus prevent damage being effected
by the sharp glass particles.

Chemical antidotes
They counteract the action of poison by forming
harmless or insoluble compounds or by oxididsing
poison when brought into contact with them .
Common salt decomposes silver nitrate by direct
chemical action , forming the insoluble silver
chloride .
Albumen precipitates mercuric chloride .
Dialysed iron is used to neutralise arsenic.
Copper sulphate is used to precipate phosphorus.
Alkalis neutralise acids by direct chemical
action.It is safer to give little weak solution
of an alkaline hydroxide , magnesia or ammonia.
Acids neutralise alkalis by direct chemical
action . Only those substances which are harmless
should be given e.g Vinegar , lemon juice ,
canned fruit juice.

Potassium permanganate has oxidising properties
15000 solution is used in poisoning for opium
and its derivatives, strychnine, phosphorus,
hydrocyanic acid, cyanides, barbituric acid and
its derivatives, atropine and other alkalis.
When it reacts with poison in stomach, it looses
its pink colour.
A solution of tincture iodine or lugols iodine 15
drops to half a glass of warm water precipitates
most alkaloids, lead, mercury, silver, quinine
and strychnine.
Tannic acid 4 o r tannin in the form of a strong
tea or one teaspoonful of tannic acid in water
tends to precipitate apomorphine,cinchona,
strychnine , nicotine, cocaine, aconite,
pilocarpine, lead, silvetr, aluminium, cvobalt,
copper, mercury, nickle and zinc.
Universal antidote When the exact poison is not
known , or when a combination of 2 or more
poisons had been taken , universal antidote is
given ,which consists of powdered animal
charcoal.2 parts magnesium oxide one part,
tannic acid one part.

Physilogical or Pharmacological antidotes
They acts on the tissues of the body and produce
symptoms exactly opposite to those caused by the
poison .
They are used after some of the poison is
absorbed in to the circulation. Their use is some
out limited and not with out danger.These agent
acts on principles of antagonism by interfering
with another action upon the enzymes,tissue cells
or opposing nerve systems.Atropine and
physostigma are 2 real physiological antidotes as
both of them affects nerve endings and produc
opposite effects on heart rate,state of the
pupils , and glandular secretory activity.

Chelating agents Are used in the treatment of
poisoning of heavy metals .They have a greater
affinity for the metals as compared to endogenous
enzymes .
B.A.L(British anti lewisite ) It is used as
physiological antidote in arsenic ,lead, bismuth,
copper, mercury,gold and other heavy metals.
E.D.T.A(Ethylenediaminetetra acetic acid)It is a
chelating agent and is effective in lead,
mercury,copper, cobalt, cadmium, iron and nickle
poisoning.
PenicillamineIts a hydrolysis product f
pencillin.It is a chelating agent of maximum
efficiency for the heavy metals.
Meso-2 3-dimercaptosuccinic acid It is used in
lead mercury and arsenic poisoning.
2,3- dimercaptopropane 1-sulfonate Is effective
in treatment of mercury lead and arsenic
Desferrioxamine It contains trivalent iron as a
chelate and is very useful in acute iron
poisoning .

76
Elimination of Poison by Excreation

Indications
In severe poisoning
Progressive deterioration inspite of full
supportive care.
When there is high risk of serious morbidity and
mortality.
When normal route of excreation of the toxic
compound is impaired.
When the poison produces delayed but serious
toxic effect.
When the patient is having cardiovascular,
respiratory or other diseases that increases the
hazard.

77
Excretion