Chemical and thermal ocular burns: a review of causes, clinical features and management protocol


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ISSN 2078-6190  EISSN 2078-6204

© 2016  The Author(s)

REVIEW

South African Family Practice 2016; 58(1):1–4
http://dx.doi.org/10.1080/20786190.2015.1085221

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Chemical and thermal ocular burns: a review of causes, clinical features and 
management protocol
Khathutshelo  Mashigea*

a School of Health Sciences, University of KwaZulu-Natal, Durban, South Africa
*Email: mashigek@ukzn.ac.za

Chemical and thermal ocular burns are among the most urgent ophthalmic emergencies, often resulting in permanent damage, 
and in some cases, blindness. These burns are the result of exposure to chemicals or radiant energy (thermal or ultraviolet). The 
most serious injuries are due to chemical burns by strong acid or bases. The purpose of managing these burns is to eliminate 
or limit the causative agent from penetrating the ocular structures by irrigation; and, promoting ocular surface healing through 
medical and surgical intervention. This review presents a current update on the causes of chemical and thermal ocular burns, 
their clinical features and the importance of appropriate and prompt treatment.

Keywords: acid burns, alkali burns, chemical burns, ocular burns, ocular irrigation

Introduction
Chemical and thermal ocular burns are among the most 
frequently reported causes of eye injuries, estimated to account 
for approximately 8-18% of ocular trauma.1−3 These burns occur 
through accidents at work, home or during leisure activities;4 
tend to be bilateral,5 and are seen more frequently in young 
males than females.6 For example, Saini and Sharma7 reported 
that young people working in laboratories and factories 
constituted two thirds of patients who experienced chemical 
injuries, and emphasised that the use of eyewear was mandatory 
when performing their duties. The injuries caused by chemical 
burns to the eye can range from mild unilateral conjunctival or 
corneal epithelial damage to sight-threatening damage to the 
conjunctiva and cornea.8 The resulting vision impairment and 
blindness has important health, socio-economic and quality-of-
life implications, which can lead to lost economic gain, and 
missed employment and educational opportunities, resulting in 
reduced quality of life generally.9 The symptoms of chemical 
ocular burns include photophobia, tearing and pain, while 
conjunctival hyperaemia, subconjunctival haemorrhage and 
chemosis are some of the presenting ocular signs of the 
condition.4 

Superficial punctuate keratitis is a sign of a mild ocular burn, 
while corneal opacification and oedema decrease the visibility of 
the iris and lens in severe burns. A mild anterior chamber reaction 
can occur.4 Typical signs of a severe burn are more than 50% loss 
of the epithelium and perilimbal ischaemia.4 These signs are 
usually coupled with “an inflammatory reaction of the anterior 
chamber, ocular hypertonia and corneal anaesthesia”,4 which 
results in the eye looking white, and indicates that there is no 
blood supply to transport the white blood cells needed to fight a 
possible infection. Timeous intervention is often key to 
preventing significant functional and anatomical damage to the 
ocular structures. The common causes, clinical features and 
management protocols of chemical thermal and ocular burns 
are discussed in this literature review.

Pathophysiology
While the course of an ocular burn depends upon the nature of 
the offending agent, chemical burns share common elements.4 

The initial phase of incineration is followed by a rush of 
inflammatory cells to produce various detergent enzymes 
(detersion), such as the matrix metalloproteinases (collagenases, 
gelatinases and stromelysin), which aggravate the destruction of 
the ocular structures.10 This is followed by a scarring phase, which 
results from the regrowth of healthy tissue surrounding the 
burn.11 The ischaemic lesions form as a result of the destruction 
of the vascular network, as well as to lesions of the corneal and 
conjunctival cells.11 Corneal and the conjunctival scarring can 
occur because the surviving cells mutate into fibroblasts, and 
also as a result of division of the stem cells.4

Chemicals can be classified as either acidic or alkaline agents.12 
Many of these are used in homes, industries and agriculture, 
causing burns when they come into contact with the eye, 
resulting in a significant threat to vision, especially those that are 
alkaline.4 The extent of the injury is influenced by various factors, 
such as the nature, quantity and concentration of the solution, 
the contact duration, solution penetrability and pH.4 While most 
burns occur from direct contact with the outer eye surfaces, 
chemicals can also reach the ocular tissue through systemic 
absorption via the skin, lungs or digestive tract.4 The intact 
cornea can resist a wide range of pH without injury, but a pH < 4 
or > 10 results in an increase in permeability, which can cause 
severe ocular complications.4

Acid burns
Automobile battery explosions are a common cause of acid burns. 
The explosive nature of the injury can lead to significant damage 
of the globe, either by contusion or perforation.4,11 Hydrofluoric, 
hydrochloric, chromic, acetic and sulphuric acid orvitriol are highly 
concentrated acids, with a pH of between 1.0 and 3.5, causing the 
worst accidents.4,11 They cause rapid damage to the superficial 
tissue structures, but tend to be neutralised in a short period 
because the protons bind with the tissue protein, and precipitate 
and denature it.4,11 Coagulation on the eye’s surface establishes a 
barrier to further penetration, resulting in most acid burns being 
confined to the superficial tissue.4 However, ocular lesions due to 
strong acids (a pH below 2.5) are deep and necrotising, affecting 
the conjunctival and limbal vessels.4

mailto:mashigek@ukzn.ac.za


2 S Afr Fam Pract  2016; 58(1):1–4

Alkali burns
The main bases of alkali include ammonia, sodium hypochlorite, 
and sodium, potassium and calcium hydroxide, which have a pH 
of between 12 and 14.4,11 Alkali burns appear to be innocuous at 
first, but rapidly progress, and are more threatening to the 
deeper tissue.11 They have poorer prognosis because the anion 
(hydroxyl) causes saponification of the fat and lipids, leading to a 
softening of the tissue, which enables increased penetration of 
the cation chemicals.4,11 Further alterations to the ocular 
structures, such as the iris, iridocorneal angle, ciliary body and 
crystalline lens, can occur because of rapid penetration of the 
alkali.4 Complete and irreversible ocular lesions occur at a pH 
above 11.5.13

The classification of chemical ocular burns
Tables 1 and 2 detail the classification of the severity of chemical 
burns by Hughes,14 updated by Roper-Hall,15 which are used 
clinically to guide treatment decisions and protocols.

The changes of limbus for grade IV burns are not accurately 
explained by the Roper-Hall classification. In 2001, Dua et al12 
proposed a new classification based on the importance of the 
deficit of limbal stem cells. The impact on vision can be 
categorised as follows:

•  Grade I-III: Vision should recover.

•  Grade IV: Usually vision is impaired to some degree, thus prog-
nosis is guarded.

•  Grade V-VI: The damage leads to severe visual impairment and 
vision loss.

Managing chemical ocular burns
The management of chemical burns normally takes one or any 
combination of three forms, namely ocular lavage, medical and 
surgery.

Ocular lavage
Irrigation with water or saline remains the most effective 
established intervention in terms of a positive prognosis and 
outcome with respect to ocular chemical burns.8,16,17 Although 
these solutions are most commonly used because they are 
readily available, newer and more effective neutralising agents 

can be used.8,17–19 These agents include a balanced salt solution, 
Ringer’s lactate, buffers and Diphoterine®.8 Urine dipsticks and 
universal indicator paper can be used to measure the conjunctival 
pH of patients with chemical burns. This process is important 
when identifying patients requiring irrigation, and should be 
continued until the pH in the conjunctival sac is neutral.4 The 
affected eye must be rinsed with at least 1.0–1.5 litres of water or 
normal saline for no less than 15 minutes.4 However, water and 
normal saline have low osmolarity, which can result in their 
increased uptake into the corneal stroma.8

Ringer’s lactate and a balanced salt solution are more effective 
than normal saline because they have the same osmolarity as 
aqueous humour.8 A balanced salt solution is routinely utilised in 
ocular surgery as it prevents corneal swelling, thus preserving 
the integrity of the corneal endothelium.20 However, it is 
expensive and not routinely used outside of theatre.20 While 
phosphate buffers are used in some emergency irrigating 
solutions, their use has been associated with stromal calcification, 
and is therefore not recommended as a first choice.17 Diphoterine® 
is a hypertonic solution and has been shown to have better 
results than a normal saline solution as it creates a movement of 
water from the hypotonic anterior chamber to the surface of the 
hypertonic cornea.19,21

Irrigating the eye should be continued until the possibility of 
chemical action is eliminated. The pH of the tears can be 
periodically tested with litmus paper to determine if the 
condition still exists, and the visual acuities checked. Pain and lid 
oedema may make conducting an objective examination 
difficult, which can be overcome by instilling a local anaesthetic, 
such as proparacaine. The local anaesthetic may also serve as a 
prognostic indicator as the drops are irritating on instillation in 
the normal eye, while the absence of irritation indicates a 
problem in eyes with severe burns and damaged corneal nerves.

Medical treatment
Local corticoids reduce inflammation by decreasing invasion of 
the corneal stroma by polynuclear neutrophils.22 Corticoids 
stabilise cell and lysosomol membranes against polynuclear 
neutrophils and antagonise the action of collagenase enzymes.22 
Although they limit conjunctival mucous cell destruction,22 they 
also reduce keratocyte migration, inhibit collagen synthesis and 

Table 1: Hughes’ classification,14 modified by Roper-Hall15

Grade Corneal alteration Limbal ischaemia Prognosis

I Epithelial damage. No corneal opacity No ischaemia Excellent

II Oedematous cornea. The iris details are visible Ischaemia less than half at limbus Good

III Total epithelial loss. Stromal oedema. The iris details are obscured Ischaemia affects one third to half of all patients at limbus Reserved

IV Opaque. The iris or pupil is invisible Ischaemia affects more than half of all patients at limbus Poor

Table 2: Dua’s classification12

Grade Analogue scale Clinical findings Conjunctival alteration (%) Prognosis

I 0.0/0.0 0 clock hours of limbal involvement 0 Very good

II 0.1-3.0/1.0-29.9 ≤ 3 clock hours of limbal involvement ≤ 30 Good

III 3.1-6.0/31.0-50.0 > 3–6 clock hours of limbal involvement > 30–50 Good

IV 6.1-9.0/51.0-75.0 > 6–9 clock hours of limbal involvement > 50−75 Good to reserved

V 9.1-11.9/75.1-99.9 > 9 < 12 clock hours of limbal involvement > 75 < 100 Reserved to poor

VI 12.0/100.0 Total limbus (12 clock hours) involvement Total conjunctiva (100%) involved Very poor



Chemical and thermal ocular burns: a review of causes, clinical features and management protocol 3

delay cicatrisation.23 The use of anti-inflammatory nonsteroidal 
treatment should be avoided as it lengthens the epithelial scarring 
process and modifies corneal sensitivity.11 The parenteral 
administration of tetracycline reduces the incidence of corneal 
ulceration and facilitates cicatrisation.24 Cycloplegics are given to 
minimise lens adhesion, as well as inflammation of the iris and 
ciliary body. The regular use of preservative-free artificial tears 
offers supportive treatment, and the local or parenteral 
administration of ascorbic acid has been reported to prevent 
corneal ulceration and retinal thinning.25 Antibiotic eyedrops and 
parenteral tetracycline are given to minimise the risk of infections; 
while analgesics, taken orally or parenterally, are prescribed 
because corneal nerve lesions can be associated with intense 
pain.11 Pressure patching is standard until re-epithelisation occurs, 
after which the person is referred for surgery.

Surgical intervention
Surgical treatment should be considered in severe burn cases, 
when the destroyed limbal stem cells need to be restored. 
Procedures such as excision, tenoplasty, preventing the 
formation of symblepharons, limbus transplantation, amniotic 
membrane transplantation, keratoplasties, cultivated epithelial 
limbus cell transportation, and conjunctival transplantation, 
using nasal or buccal mucous membrane samples, are used 
depending on the severity of the burn and the desired 
outcome.4,11

Thermal and radiation burns
Thermal burns
Damage due to thermal burns occurs at the time of injury. Most 
commonly, the causes are boiling liquid, molten metal, flames, 
gasoline explosions, steam and hot tar.4 The extent of damage 
and impact on vision depend on the degree of the heat agent, 
area and duration of contact, as well as conductance of the 
tissue.4 If the burn is caused by a flame, the eyelashes and lids are 
mainly affected because of the speed of the protective blink 
response.4 When the eye is not protected, severe thermal ocular 
lesions are mainly associated with grade III cutaneous burns.26 
The mainstay treatment options for superficial lesions caused by 
thermal burns include a combination of local antibiotherapy, 
instillation of artificial tears, application of an occlusive dressing 
(until re-epitheliasation), and sometimes cycloplegia.4 Common 
complications include retractile palpebral scars owing to 
conditions such as trichiasis, entropion or ectropion.4

Radiation burns
Sources of ultraviolet (UV) radiation are varied, and include those 
which are highly directional from the sun, diffuse and directional 
from the sun, and diffuse and specularly reflected from various 
surfaces on earth, e.g. snow, sand and water.27 The amount of UV 
radiation varies with the time of day, angle of the sun, cloud 
cover and changes in the reflecting surfaces. Excessive exposure 
to UV radiation is associated with the development of pterygia, 
ocular neoplasms, photokeratitis, age-related cataracts and 
irreversible damage to the retina.27 Preventive measures include 
wearing protective eyewear with UV-blocking tints.27 Infrared (IR) 
radiation causes superficial punctate keratitis to the cornea, 
which has been reported to secondarily induce an increase in 
intraocular pressure.28 When sufficient IR is absorbed by the iris, 
this can lead to pupillary miosis, aqueous flare (because of a 
breakdown in the blood aqueous barrier), hyperaemia and post 
synechiae.28 IR on the lens produces anterior subcapsular 
opacities which first appear as discrete “whitish dots”, and can 
lead to a network-like whitish opacity with sufficient exposure. 
This does not migrate towards the equator or post capsule, but 

fades and disappears within six weeks.28 Laser IR can also cause 
chorioretinitis and retinal pigment epithelium thermal injury. To 
avoid the effects of IR on the ocular structures, protective wear, 
such as helmets and shields with filters, should be worn, 
particularly by glass blowers and steel workers.28 Neutral grey to 
yellow tints, which provide protection against most optical 
radiation, are recommended.28 Metallic oxide incorporated into 
glass absorbs 95% of UV and IR. Reflective filters vacuum-coated 
onto the front surface of the lens reflect unwanted IR.28 Burns by 
UV and IR radiation, which cause cataracts or chorioretinitis, may 
lead to visual acuity deterioration and vision loss.

Conclusion
Akali injuries are more common than acid injuries as they are 
included more frequently in household cleaning agents, as well 
as industrial and building materials. Copious irrigation with 
water, saline solution or an agent, such as phosphate buffer, 
lactated Ringer’s solution, a balanced salt solution, and 
Diphoterine® solution (to achieve therapeutic goals), is the most 
important and immediate intervention for chemical ocular 
burns. Medical and surgical management depends on the clinical 
findings. Cycloplegics are given to minimise lens adhesion, 
inflammation of the iris and ciliary body, while topical antibiotics 
are provided to minimise the risk of infection. Ocular burns in 
industries can be reduced through occupational health laws 
which educate workers and promote the use of safety eyewear.

Acknowledgements – The author acknowledges Carrin Martin for 
commenting on the manuscript.

Conflict of interest – The author declares that there was no 
conflict of interest which might have inappropriately influenced 
him when writing this paper.

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Available from: http://www.optometry.co.uk/uploads/
articles/33aa07d53d20b5cbc6f17ffc81f0dc94_Voke1990521.pdf.

Received: 09-03-2015 Accepted: 18-08-2015

http://www.optometry.co.uk/uploads/articles/33aa07d53d20b5cbc6f17ffc81f0dc94_Voke1990521.pdf
http://www.optometry.co.uk/uploads/articles/33aa07d53d20b5cbc6f17ffc81f0dc94_Voke1990521.pdf

	Introduction
	Pathophysiology
	Acid burns
	Alkali burns
	The classification of chemical ocular burns
	Managing chemical ocular burns
	Ocular lavage
	Medical treatment
	Surgical intervention

	Thermal and radiation burns
	Thermal burns
	Radiation burns

	Conclusion
	Acknowledgements
	Conflict of interest
	References