Review: the use of sodium hypochlorite in endodontics — potential complications and their management

Key Points

  • Sodium hypochlorite is a commonly used irrigant in endodontic practice. It has many potential complications ranging from permanent bleaching of clothes to severe soft tissue damage.

  • The complications of hypochlorite extrusion beyond the root apex are discussed.

  • Guidelines are given for the safe use of hypochlorite solution during endodontic treatment and advice on the appropriate course of action when a hypochlorite complication is suspected.


Aqueous sodium hypochlorite (bleach) solution is widely used in dental practice during root canal treatment. Although it is generally regarded as being very safe, potentially severe complications can occur when it comes into contact with soft tissue. This paper discusses the use of sodium hypochlorite in dental treatment, reviews the current literature regarding hypochlorite complications, and considers the appropriate management for a dental practitioner when faced with a potentially adverse incident with this agent.


Sodium hypochlorite (NaOCl) was first recognised as an antibacterial agent in 1843 when hand washing with hypochlorite solution between patients produced unusually low rates of infection transmission between patients. It was first recorded as an endodontic irrigant in 19201 and is now in routine worldwide use.

Sodium hypochlorite is used as an endodontic irrigant as it is an effective antimicrobial and has tissue-dissolving capabilities. It has low viscosity allowing easy introduction into the canal architecture, an acceptable shelf life, is easily available and inexpensive. The toxicity of its action to vital tissues and corrosion of metals2 are its main disadvantages in dental use. Sodium hypochlorite reacts with fatty acids and amino acids in dental pulp resulting in liquefaction of organic tissue.3 There is no universally accepted concentration of sodium hypochlorite for use as an endodontic irrigant. The antibacterial and tissue dissolution action of hypochlorite increases with its concentration, but this is accompanied by an increase in toxicity. Concentrations used vary down from 5.25% depending on the dilution and storage protocols of individual practitioners. Solution warmers are available to increase the temperature up to 60°C. Increasing the temperature of a solution of hypochlorite improves the bactericidal and pulp dissolution activity, although the effect of heat transfer to the adjacent tissues is uncertain.4

As a bleaching agent, inadvertent spillage of this agent can result in damage to clothing and soft tissues. Inadvertent introduction of sodium hypochlorite beyond the root canal system may result in extensive soft tissue or nerve damage, and even airway compromise. This article reviews the potential complications that can occur with sodium hypochlorite in clinical practice, discusses measures that can be taken to minimise risk, and provides details of appropriate management in the rare cases of suspected tissue damage.

Complications of accidental spillage

1) Damage to clothing

Accidental spillage of sodium hypochlorite is probably the most common accident to occur during root canal irrigation. Even spillage of minute quantities of this agent on clothing will lead to rapid, irreparable bleaching. The patient should wear a protective plastic bib, and the practitioner should exercise care when transferring syringes filled with hypochlorite to the oral cavity.

2) Eye damage

Seemingly mild burns with an alkali such as sodium hypochlorite can result in significant injury as the alkali reacts with the lipid in the corneal epithelial cells, forming a soap bubble that penetrates the corneal stroma. The alkali moves rapidly to the anterior chamber, making repair difficult. Further degeneration of the tissues within the anterior chamber results in perforation, with endophthalmitis and subsequent loss of the eye.5

Ingram recorded a case of accidental spillage of 5.25% sodium hypochlorite into a patient's eye during endodontic therapy.6 The immediate symptoms included instant severe pain and intense burning, profuse watering (epiphora) and erythema. Loss of epithelial cells in the outer corneal layer may occur. There may be blurring of vision and patchy colouration of the cornea.7 Immediate ocular irrigation with a large amount of water or sterile saline is required followed by an urgent referral to an ophthalmologist.8 The referral should ideally be made immediately by telephone to the nearest eye department. The use of adequate eye protection during endodontic treatment should eliminate the risk of occurrence of this accident, but sterile saline should always be available to irrigate eyes injured with hypochlorite. It has been advised that eyes exposed to undiluted bleach should be irrigated for 15 minutes with a litre of normal saline.9,10

3) Damage to skin

Skin injury with an alkaline substance requires immediate irrigation with water as alkalis combine with proteins or fats in tissue to form soluble protein complexes or soaps. These complexes permit the passage of hydroxyl ions deep into the tissue, thereby limiting their contact with the water dilutant on the skin surface.

Water is the agent of choice for irrigating skin and it should be delivered at low pressure as high pressure may spread the hypochlorite into the patient's or rescuer's eyes.5

4) Damage to oral mucosa

Surface injury is caused by the reaction of alkali with protein and fats as described for eye injuries above. Swallowing of sodium hypochlorite requires the patient to be monitored following immediate treatment. It is worth noting that skin damage can result from secondary contamination.

Allergy to sodium hypochlorite

The allergic potential of sodium hypochlorite was first reported in 1940 by Sulzberger11 and subsequently by Cohen and Burns.12 Caliskan et al. presented a case where a 32-year-old female developed rapid onset pain, swelling, difficulty in breathing and subsequently hypotension following application of 0.5 ml of 1% sodium hypochlorite.13 The patient required urgent hospitalisation in the intensive care unit and management with intravenous steroids and antihistamines. A subsequent allergy skin scratch test performed two weeks after the patient was discharged confirmed a highly positive result to sodium hypochlorite. The usefulness of this test in suspected cases of sodium hypochlorite allergy during endodontic treatment has been confirmed by Kaufman and Keila.14 Even though allergy to sodium hypochlorite is rare, it is important for clinicians to recognise the symptoms of allergy and possible anaphylaxis. These may include urticaria, oedema, shortness of breath, wheezing (bronchospasm) and hypotension. Urgent referral to a hospital following first aid management is recommended.

Complications arising from hypochlorite extrusion beyond the root apex

1) Chemical burns and tissue necrosis

When sodium hypochlorite is extruded beyond the root canal into the peri-radicular tissues, the effect is one of a chemical burn leading to a localised or extensive tissue necrosis. Given the widespread use of hypochlorite, this complication is fortunately very rare indeed. A severe acute inflammatory reaction of the tissues develops. This leads to rapid tissue swelling both intra orally within the surrounding mucosa and extra orally within the skin and subcutaneous tissues. The swelling may be oedematous, haemorrhagic or both,15 and may extend beyond the region that might be expected with an acute infection of the affected tooth16,17 (Figs 1, 2). Sudden onset of pain is a hallmark of tissue damage, and may occur immediately or be delayed for several minutes or hours.18 Involvement of the maxillary sinus will lead to acute sinusitis.19 Associated bleeding into the interstitial tissues results in bruising and ecchymosis of the surrounding mucosa and possibly the facial skin (Fig. 3) and may include the formation of a haematoma.15,20 A necrotic ulceration of the mucosa adjacent to the tooth may occur as a direct result of the chemical burn.21 This reaction of the tissues may occur within minutes or may be delayed and appear some hours or days later.20,22 If these symptoms develop, urgent telephone referral should be made to the nearest maxillofacial unit. Patients will be assessed by the on call maxillofacial team. Treatment is determined by the extent and rapidity of the soft tissue swelling but may necessitate urgent hospitalisation and administration of intravenous steroids and antibiotics.7,18 Although the evidence for the use of antibiotics in these patients is anecdotal, secondary bacterial infection is a distinct possibility in areas of necrotic tissue and therefore they are often prescribed as part of the overall patient management. Surgical drainage or debridement may also be required depending on the extent and character of the tissue swelling and necrosis.7,18,19

Figure 1

Bruising and oedema of three patients who presented with hypochlorite extrusion into the soft tissues

Figure 2

Bruising and oedema of three patients who presented with hypochlorite extrusion into the soft tissues

Figure 3

Bruising and oedema of three patients who presented with hypochlorite extrusion into the soft tissues

2) Neurological complications

Paraesthesia and anaesthesia affecting the mental,22 inferior dental22 and infra-orbital branches18,22,23 of the trigeminal nerve following inadvertent extrusion of sodium hypochlorite beyond the root canals have been described. Normal sensation may take many months to completely resolve.22,23

Facial nerve damage was first described by Witton et al. in 2005.18 In both cases, the buccal branch of the facial nerve was affected. Both patients exhibited a loss of the naso-labial groove and a down turning of the angle of the mouth. Both patients were reviewed and their motor function was regained after several months. Sensory and motor nerve deficit are not commonly associated with acute dental abscesses. As there is no other current evidence in the literature it is possible that these neurological complications were a direct result of chemical damage by sodium hypochlorite, but further research (including nerve conduction studies) is required.

3) Upper airway obstruction

The use of sodium hypochlorite for root canal irrigation without adequate isolation of the tooth can lead to leakage of the solution into the oral cavity and ingestion or inhalation by the patient. This could result in throat irritation22 and in severe cases, the upper airway could be compromised. Ziegler presented a case of a 15-month-old girl who presented in the accident and emergency unit with acute laryngotracheal bronchitis, stridor and profuse drooling from the mouth as a result of ingestion of a high concentration of household sodium hypochlorite.24 A similar clinical presentation might occur with the ingestion of any caustic substance.25 Opinion varies as to the best concentration of hypochlorite, with some practitioners using undiluted household bleach.20 Fibre optic nasal tracheal intubation followed by surgical decompression has been required to manage airway compromising swelling arising within three hours of accidental exposure to sodium hypochlorite during root canal treatment (Fig. 4).26

Figure 4

Upper airway compromise requiring decompression following extrusion of hypochlorite into the soft tissues

What can I do to minimise the risk of hypochlorite complications?

The use of all chemicals or hazardous substances in practice is covered by legislation requiring employers to control exposure to both staff and patients to prevent ill health. The Control of Substances Hazardous to Health Regulations (2002) (COSHH)27 requires a practice to prepare plans and procedures to deal with accidents, incidents and emergencies involving hazardous substances and to adequately control exposure.

As has already been stated, these are rare complications, but nonetheless, the risk of hypochlorite-induced damage can be minimised by implementing the measures listed in Table 1 when performing endodontic therapy. If the aqueous sodium hypochlorite is to be diluted for use, eye protection, face mask, gloves and plastic apron should be worn for the procedure. The prepared solution must be stored in a lightproof, non-metallic container that is appropriately labelled.

Table 1 Preventive measures that should be taken to minimise potential complications with sodium hypochlorite

During treatment the patient's clothing should be protected with a bib that is impermeable to liquid. The patient and clinical team should wear well fitting protective glasses. Rubber dam should be used to isolate the tooth and minor defects in adaptation corrected with a caulking agent to optimise the seal. If the canal is to be irrigated using a needle and syringe, the needle must be side venting. The use of hypodermic (end exiting) needles in root canal irrigation risks accidental inoculation into the soft tissues.

Only Luer-Lok style syringes and needles should be used, as taper seat needles may dislodge in use, with uncontrolled loss of the hypochlorite solution under pressure.29,30 The needle should not engage the sides of the canal, but be loosely positioned within the canal. The needle should not reach the apical extent of the prepared canal.30 This technique may be facilitated by marking the working length on the needle with a rubber stop (Fig. 5). The irrigant is delivered slowly with minimal pressure to reduce the likelihood of forcing it through the apex. This is most easily achieved by using your index finger rather than thumb to depress the plunger.30 This will reduce the risk to periapical tissues by inadvertent extrusion of irrigant.

Figure 5

Placement of rubber stop on irrigation needle

Particular care must be taken in immature teeth with open apices to ensure that the irrigant does not go into the apical tissues. Sodium hypochlorite and saline are both recommended for irrigation in immature teeth, however, if hypochlorite is used it has been suggested the final irrigation should be with saline to remove any hypochlorite from the canal.31

In keeping with the COSHH regulations,27 clinicians would also be required to prevent or adequately control exposure to sodium hypochlorite as far as is reasonably practicable. This may include changing the treatment plan to eliminate the need for sodium hypochlorite, using a replacement or using it in a safer form eg a dilute but equally active concentration.

Spangberg and Langeland carried out a series of in vivo and in vitro tests on various potential irrigants.32 They found that as well as being highly toxic and irritating, 5% sodium hypochlorite was considerably stronger than necessary to kill the bacteria in the root canal, while 0.5% concentration dissolves necrotic tissue but has no effect on Staphylococcus aureus. They therefore recommended the ideal solution to be one that combines maximal antimicrobial effect with minimal toxicity. These results were confirmed by Yesiloy et al., who found that the antimicrobial effects of sodium hypochlorite were much less with concentrations of 2.5% and lower.33 They also found that chlorhexidine gluconate 0.12% has the equivalent antimicrobial effect to 5.25% sodium hypochlorite. It has been shown that chlorhexidine-treated root canals are less susceptible to re-infection.34 Chlorhexidine is the irrigant of choice in re-treatment cases.30 However, sodium hypochlorite remains the most commonly used and recommended endodontic irrigant as it alone combines antimicrobial and tissue dissolving capabilities essential in teeth not previously root filled.

What should I do if I suspect a hypochlorite complication?

No standard therapy for the management of complications has been documented, probably because these complications are rare and sporadic.

Initial management

Tissue swelling can potentially be minimised by using cold compression (frozen items wrapped in a towel). If the patient is being treated under local anaesthesia they may not experience pain immediately. Mild to moderate pain may be managed with analgesia such as ibuprofen and paracetamol.8 Adult doses of paracetamol 1 g qds and ibuprofen or ibuprofen 400 mg qds can be used alternately at four hourly intervals if necessary. Oral antibiotics may also be prescribed to minimise the risk of secondary bacterial infection; Amoxicillin 250 mg tds or Metronidazole 200 mg tds in the penicillin allergic patient. It should be emphasised that careful patient record keeping is very important in clinical practice. The precise details of the event should be documented including concentration and volume of the hypochlorite solution involved. The measures employed to minimise risk (eg rubber dam, eye protection, working length measurement) should also be documented. Clinical photographs may also be appropriate to supplement the notes.

Conservative management for hypochlorite complications has been recommended.28 While this may be appropriate in patients who develop mild complications, it is not to be universally recommended. Urgent referral is necessary in all cases involving ingestion or inhalation of hypochlorite, as the clinical consequences cannot be predicted from the oropharyngeal symptoms. Maxillofacial advice and assessment is recommended for any suspected hypochlorite complication.

In summary, this review discusses the potential complications that can occur with sodium hypochlorite in endodontic dental practice. Although rare, the recognition and subsequent primary management by the dental practitioner of these complications is essential to ensure best clinical practice.

Table 2 Emergency management of accidental hypochlorite damage


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Correspondence to P. A. Brennan.

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Spencer, H., Ike, V. & Brennan, P. Review: the use of sodium hypochlorite in endodontics — potential complications and their management. Br Dent J 202, 555–559 (2007).

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