Chemical burns - pathophysiology and treatment - handout
1. Adapted from Palao et al, Chemical burns: Pathophysiology and treatment, Burns, 36 (2010) 295 – 304
Chemical burns: Pathophysiology and treatment
Chemicals that can cause burns are numerous and common in industry, agriculture, and households and increasingly in
domestic violence and warfare. Harm potential is often underestimated. Chemical burns are rare (3%) but carry
significant morbidity and mortality (55% require surgery, 30% of burn deaths). See original article for images.
Pathophysiology
All burns cause protein denaturation, however chemical burns tend to be:
Associate with longer duration of exposure
Ongoing in the ED
Caused by more complex mechanisms than protein cross-linking and coagulation (e.g. hydrolysis)
Severity depends on:
(a) Concentration
(b) Quantity of burning agent
(c) Duration of skin contact
(d) Penetration
(e) Mechanism of action.
6 Mechanisms of action
(1) Oxidation: The protein denaturation is caused by inserting an oxygen, sulphur, or halogen atom to viable body
proteins. E.g. sodium hypochlorite, potassium permanganate, and chromic acid.
(2) Reduction: Reducing agents act by binding free electrons in tissue proteins. Heat from exothermic reaction may
cause a mixed picture. E.g. hydrochloric acid, nitric acid and alkyl mercuric compounds.
(3) Corrosion: Corrosive agents cause protein denaturation on contact. Produce a soft eschar, which may progress
to shallow ulceration. E.g. phenols, sodium hypochlorite, and white phosphorous.
(4) Protoplasmic poisons: Produce their effects by causing the formation of esters with proteins or by binding or
inhibiting calcium or other organic ions necessary for tissue viability and function. E.g. ester formers: formic and
acetic acids, inhibitors: oxalic and hydrofluoric acids.
(5) Vesicants: produce ischemia with anoxic necrosis at the site of contact. Characterized to produce cutaneous
blisters. E.g. mustard gas, dimethyl sulfoxide (DMSO), and Lewisite.
(6) Desiccants: cause damage by dehydration of tissues. Often exacerbated by heat production due to exothermic
reactions. E.g. sulphuric and muriatic (concentrated hydrochloric) acids.
Classification by type of chemical
1. Acids: Proton donors. Release H+
ions and ↓pH from 7 down to values as low as 0. Acids with a pH < 2 can
produce coagulation necrosis on contact with the skin. A better predictor than pH alone is the amount of alkali
needed to raise the pH of an acid to neutrality. This may reflect the strength of the acid involved.
2. Bases: Proton acceptors. Strip H+
ions from protonated amine groups and carboxylic groups. Alkalis with a pH >
11.5 produce severe tissue injury through liquefaction necrosis, which loosens tissue planes and allows deeper
penetration of the agent. For this reason, alkali burns tend to be more severe than acid burns.
3. Organic solutions act dissolving the lipid membrane of cells and disrupting the cellular protein structure.
4. Inorganic solutions damage the skin by direct binding and salt formation.
It should be noted that all of these reactions may be accompanied by exothermy, which contributes to tissue injury.
Farooq Khan MDCM
PGY3 FRCP-EM
McGill University
November 14
th
2011
2. Adapted from Palao et al, Chemical burns: Pathophysiology and treatment, Burns, 36 (2010) 295 – 304
Management
General principles
In addition to standard ATLS and Burn care, stabilisation, consultation with Poison Control, and transfer to Burn Units:
Material Safety Data Sheets are mandated to be available for all chemicals present in the workplace, which can be
valuable resources for potential systemic toxicity and side-effects of an agent.
Decontamination
Remember to remove clothing
Early and copious water irrigation (0.5 – 2h) has been shown to reduce the severity of burn and hospital LOS
Monitoring of the lavage solution pH will give a good indication of lavage effectiveness and completion
Maintain 28-30° temperature for copious lavage to avoid hypothermia
Note exceptions to lavage above:
o sulphuric and muriatic acids cause severe exothermic reaction with water
o dry lime creates calcium oxide, potent alkali, in combination with water
Neutralizing agents
Controversial theoretical benefits
Ideal agent would be sterile polyvalent (actively binds multiple substances), amphoteric, hypertonic, chelating
molecule with active binding sites for acids, bases, oxidizing agents, reducing agent, vesicant, lachrymators,
irritants, solvents, etc. E.g. Diphoterine being used in Europe
Risks include:
o Agents own toxicity (may need toxic dose of antidote to neutralize amount of chemical)
o Potential for exothermic reaction
o Delay of hydrotherapy
3. Adapted from Palao et al, Chemical burns: Pathophysiology and treatment, Burns, 36 (2010) 295 – 304
Estimation of burns and local care
ABCs and resuscitation following thermal burn formulas
Assessment of depth and extent is challenging due to tanning and anaesthetic properties of some chemicals, i.e.
deep burns can appear deceptively superficial
Lavage and excision of blisters
Chemotherapeutic agents, creams, dressings
Early excision and grafting of non-viable tissue
Ocular injury mandates Ophthalmology consultation, early copious irrigation is standard but new evidence to
suggest it may have some harm, research ongoing into neutralizing agents (e.g. Diphoterine)
Systemic toxicity and inhalational injury
Monitor end organ perfusion
Check pH and extended electrolytes
Examples of systemic toxicity
o HF – hypocalcemia and V-fib
o Formic acid – intravascular hemolysis, renal failure, pancreatitis
Aerosolize chemical exposures should be treated like smoke inhalation injuries, with O2, early intubation and
mechanical ventilation using ARDS-like strategies
6 Specific agents
Cement
Mechanisms of injury
(1) Allergic dermatitis: caused by the reaction to its hexavalent chromate ions. Irritation from the sand and
gravel within cement can similarly cause dermatitis.
(2) Abrasions: The gritty nature of the coarse and fine aggregate in the cement is responsible for these lesions.
(3) Chemical Burns: Most significant injuries. 65% calcium oxide (CaO) which is an alkali and dessicant. On
contact with water becomes calcium hydroxide (Ca(OH)2), also alkali that can cause liquefaction necrosis.
Patients unaware of risks and insidious onset of symptoms (hours)
Commonly deep injuries to lower extremities
Remove clothing, clean with sterile water, apply topical antibiotic cream
Evaluate periodically for need for surgical excision and skin grafting
Special care of ocular and aerosolized exposures
Hydrochloric/muriatic acid
Denatures proteins into chloride salts
Needs quick and continuous irrigation
Can produce upper airway edema and ARDS if fumes inhaled
Hydrofluoric acid
Easily available and present in the community. Used in frosting, etching and polishing glass and ceramics,
removal of metal castings, cleaning stone and marble, and in the treatment of textiles
Stored as a colourless liquid
Causes severe burns and systemic effects, despite minimally apparent cutaneous damage
o H+
ions cause superficial burns
4. Adapted from Palao et al, Chemical burns: Pathophysiology and treatment, Burns, 36 (2010) 295 – 304
o Fl-
penetrates down to the deeper soft tissue
interferes with cellular metabolism causing cell death and liquefactive necrosis
binds Ca++
and Mg++
causing systemic hypocalcemia and hypomagnesemia
inhibits Na+
-K+
ATPase causing efflux of K+
and E+
shifts at nerve endings causing extreme pain
Clinical presentation depends on:
o route of exposure
Wide variety of systemic cardiac, respiratory, GI and neurological effects
o concentration of acid
>50% - immediate tissue destruction and pain
20-50% - burns become apparent within hours
<20% - may take up to 24h to appear
o duration of contact
o penetrability or resistance of the tissue exposed
Most frequently in digits, subungual area. Can be other skin, ocular, inhalational or digestive
Symptoms typical of ↓Ca++
and ↓Mg++
generally absent
o Serum calcium levels and electrocardiogram (↑QT) are important monitors
o Fl-
may be direct myocardial irritant and can be removed by HD
Treatment includes four phases:
o Hydrotherapy – immediate and prolonged
o Topical treatment – Controversial. Try to inactive Fl-
and create insoluble fluoride salt.
Mg compounds: generally ineffective and anecdotal
Quaternary ammonium compounds (e.g Hyamine) Multiple proposed mechanisms, but may be
too toxic in doses required to neutralize 1 cc of 20% HF solution.
Ca++
gel: easily applied, but poorly permeable and stains skin
o Infiltration – Ca++
gluconate 10% 0.5ml SC/cm2
of burned tissue until painless. Consider nail removal
o Intra-arterial infusion – CaCl2 in severe digital burns with large amount of Fl-
ions to be neutralized.
Controversial as exposure may be fatal despite treatment
Phosphorus
Most frequently used in military where
White phosphorus ignites in the presence of air and burns until the entire agent is oxidized or the oxygen source
is removed
Irrigation with water is the most important point of treatment
Removal of macroscopic clusters of phosphorus in contact with patient. Application of a 0.5% copper sulphate
solution impedes oxidation and turns the particles black, making identification and removal easier.
Alteration of calcium, phosphorus or cardiac changes can occur
Strong Alkali
Lime(CaO + Ca(OH)2), NaOH, and KOH present in many household cleaners
Mechanisms
1. Saponification of fat is an exothermic reaction severe tissue damage through heat. Destruction of fat allows
increased water penetration of the alkali into the burn eschar, destroying the natural water barrier of lipids.
2. Extraction of considerable water from cells causes damage due to the hygroscopic nature of alkalis, causing
extensive cell death and damage to tissues.
3. Alkalis dissolve proteins of the tissues to form alkaline proteinates, which are soluble and contain OH-
ions that
cause further chemical reaction initiating deeper tissue injury (liquefaction necrosis).
5. Adapted from Palao et al, Chemical burns: Pathophysiology and treatment, Burns, 36 (2010) 295 – 304
All clothes should be removed and the dry residues of alkali (e.g. lime) should be brushed away
Washing induces :
- dilution and elimination of a chemical substance
- attenuation of the chemical and exothermic reaction
- suppression of any raised tissue metabolism
- anti-inflammatory action
- suppression of the hygroscopic action
- return skin pH levels to normal
Irrigate 2h with 4h rest, maintain body temp. and use appropriate tanks with drains (esp. for large BSA)
Once stable, tangential excision of deep burned tissue with skin grafting
Sulphuric acid
Non-occupational exposures can be related to violence and often involve drain cleaner
Along with precursor sulphur trioxide cause dehydration and excessive heat in tissues leading to tissue coagulation
and microvascular thrombi.
Remove clothing and irrigate with soda lime/soap wash before copious lavage with water
Nitric oxide burns similar but may look deceptively superficial
Vesicant chemical warfare agents
Lewisite (L) and Sulphur Mustard (SM) gases
Affects all epithelia with initial symptoms of burning eyes/throat and suffocation
Delayed (24h) partial thickness injury with large bullae and delayed healing (months) due to damaged dermis
Severity of lesion dependent upon the dose of the agent, ambient temperature and moisture level in the skin
Blister aspiration and/or deroofing, epidermal removal, physical debridement, irrigation, topical antibiotics and
sterile dressings to treat cutaneous SM burns