Hydrofluoric Acid Injuries and Illness for First Responders
The recent siege on the US Capitol highlights a dark time in American history. Even peaceful protests can turn violent. Emergency physicians, tactical medical providers, and other first responders are tasked with taking care of those who become injured or ill in such gatherings. Hydrofluoric acid (HF) was likely used in incidents of vandalism during protests in Portland, Oregon this past year (1). Accidental or intentional exposure of law enforcement officers (LEO), other first responders, protestors and bystanders to HF acid should therefore be planned for by emergency personnel especially given the complexity of treatment and the potentially fatal nature of HF toxicity. This article reviews the literature regarding presentation, pathophysiology and treatment of the chemical burns and systemic effects associated with HF.
Hydrofluoric acid is an inorganic acid historically used for its corrosive properties in domestic and industrial settings. More recently, HF is being used at low levels in the manufacture of cleaning supplies, rust removers, fertilizer, pesticides, and some plastics (2). Indeed, most of our knowledge about HF exposures comes from occupational exposures. HF is most commonly encountered as a colorless liquid similar to water in appearance or as a gas. It has a strong, irritating odor, although it may reach harmful levels without the odor being detected. Even small quantities of HF can cause life-threatening burns and systemic effects (3). Diagnosis of systemic toxicity may be delayed, as HF liquid often appears innocuous, and symptoms of exposure may not present immediately. Delays in treatment may result in devastating consequences for the patient.
Mechanism of Injury
HF acid toxicity can occur via contact with skin or eyes, inhalation, or ingestion. All of these initial contacts can lead to severe local and systemic effects.
Toxicity results from the weak HF acid penetrating deep into the skin and underlying tissue before dissociating into hydrogen and fluoride ions, allowing fluoride anions into fascia, muscle, bone and the circulatory system (4). Fluoride anions sequester calcium, magnesium and manganese cations causing precipitous drops in these levels. Local and systemic hyperkalemia may ensue as cell membrane permeability to potassium is increased by local calcium depletion. Hypokalemia may result as well, though the mechanism is not clearly understood. Hypocalcemia, hypomagnesemia and hyper- and hypokalemia may lead to fatal dysrhythmias. Fluoride ions are believed to be directly toxic to myocardial cells by inhibiting adenylate cyclase. Locally, fluoride ions are thought to directly inhibit Na+/K+ pumps, which creates local hyperkalemia with resultant neuronal depolarization and significant pain. HF is highly lipophilic causing liquefactive necrosis of deeper tissues resulting in the hallmark finding of HF burns: “pain out of proportion to exam.”
Clinically, the toxicity of HF exposure is directly proportional to
- the concentration of HF;
- the duration of exposure;
- the immediacy and adequacy of first aid measures, such as irrigation;
- the extent of body surface area exposed.
HF causes local injury via two primary mechanisms: as an immediate burn and as a delayed burn with skin penetration (5). At high HF concentrations (>50%), the hydrogen ion causes a corrosive burn similar to other acid burns, with immediate visible tissue damage (2). immediate pain followed by the development of grey areas, necrosis or ulceration. Late manifestations may include tenosynovitis and osteolysis.
At lower HF concentrations, which represent a majority of HF burns, immediate visible tissue destruction does not occur and there may be no initial evidence of chemical burn. Symptoms may be delayed up to 24 hours. Unfortunately, outside of an occupational or household exposure, such as in an intentional attack, the concentration may not be known. Immediate burns and pain from high HF concentration exposures may actually have better prognosis as lower concentration asymptomatic burns may go undetected till severe local and systemic effects are already widespread.
Inhaled HF leads to symptoms related to local irritation, upper airway edema, non-cardiogenic pulmonary edema, reactive airway disease, and systemic absorption. Clinical findings include mouth and throat pain, stridor, wheezing and dyspnea.
Ingested HF is less common and often the result of accidental or intentional ingestion of low HF concentration household products (6). Clinical manifestations related to local irritation include burning in the throat, esophagitis, gastritis, hemorrhagic pancreatitis, small bowel edema with resulting nausea, abdominal pain, vomiting, GI bleeding, and liver failure. Ingestion is often associated with rapid mortality, and those who do not die immediately may develop significant systemic toxicity.
Systemic HF toxicity can be difficult to manage. The effects are primarily related to massive electrolyte disturbances, mainly hypocalcemia, hypomagnesemia, acidosis, fluorosis, and hyper- or hypokalemia. Such disturbances can lead to severe alterations in renal, hepatic and cardiac function (7). Along with the symptoms associated with the mechanism of exposure, patients may present with headaches, seizures, paresis, coma, hypotension, and cardiac arrhythmias. Signs of systemic HF toxicity include prolonged QT, cardiac failure, renal failure, coagulation disorders, and rhabdomyolysis (8). These manifestations may be immediate or delayed. Although toxicity is less likely to occur in minor cutaneous exposures involving low concentrations of HF (9) the provider must remain vigilant for systemic effects even in this situation. One case describes a patient with 3% BSA splash exposure to 20% HF who received immediate irrigation and calcium gluconate treatment, and yet suffered cardiac arrest related to severe electrolyte imbalance (10).
Systemic toxicity is a feared complication of acute HF exposure, especially in the potential setting of attacks against first responders, terrorist attacks, accidental exposures, riots, and protests. In these settings, patients may not readily be aware of their contact and decontamination and treatment might be delayed. First responders must be acutely aware of the possibility of exposure and all patients require rapid assessment.
Tactical assessment precedes treatment, ensuring mitigation of active threats and the ability of medical providers to safely administer care. Immediate field care should focus on ABC’s and decontamination. Patients should be triaged based on severity of injuries and if HF exposure is suspected, providers should begin immediate decontamination with water or normal saline (NS).
Local pain can be used as a gauge of severity of exposure and HF concentration in unknown situations and helps guide triage and treatment. If the patient experiences severe, immediate pain, an exposure to >50% HF should be suspected. If pain is delayed initially but develops within hours, HF concentration between 20-50% should be suspected. If local pain develops 12 to 24 hours after exposure, suspect HF concentrations <20%. Exposure to >50% HF of any amount is of significant concern for life threatening electrolyte abnormalities. >5% TBSA with any concentration of HF is similarly higher risk for life threatening electrolyte abnormalities.
Prehospital Treatment Principles:
- Skin irrigation with water should be initiated immediately to dilute and remove HF from the skin. Irrigation should be performed for 20-30 minutes. Delay of irrigation until arrival to the hospital results in significantly more full-thickness injury, increased likelihood of systemic effects as well as a hospital stay that is twice as long compared with those who received immediate decontamination after HF chemical injury (11). Make sure all jewelry is removed and the skin underneath is irrigated.
- Following irrigation, calcium gluconate gel should be applied to the affected skin in order to bind the cutaneous free fluoride ions and prevent penetration into the deeper tissues (11). Because calcium ions have poor tissue penetration, the gel can only neutralize fluoride ions on the surface or the superficial skin layers. The gel can be purchased or made by mixing a water-soluble lubricant with a calcium gluconate solution or calcium gluconate powder (75 mL lubricant plus 25 mL of 10% calcium gluconate or 100 mL of lubricant plus 2.5 g of calcium gluconate powder) (12). This gel must be massaged into the affected area. Application of the gel should occur every 30 minutes initially and tapered down to every 4 hours until pain relief is achieved (13). Since there is such poor penetration of calcium into the deeper tissues, DMSO has been used as an agent to improve absorption. There is currently no consensus on use of DMSO, but this remains an option in contemporary literature (14). The person applying the gel must wear gloves to avoid self-contamination. One trick of the trade for treating hand exposures is to place the calcium gel in a large surgical glove then have the patient place their hand inside the glove.
- Inhalational exposure can be treated with nebulized 2.5% calcium gluconate. (1.5 mL of 10% calcium gluconate in 4.5 mL of NS nebulized)
- For ingested HF, the conscious patient should be encouraged to drink large amounts of water to dilute the HF followed by several glasses of milk or several ounces of Maalox, Mylanta or crushed Tums. Do NOT induce vomiting.
- Institute immediate cardiac monitoring. A 12 lead ecg should be obtained as soon as possible to look for QT prolongation.
- If severe systemic toxicity is suspected, immediately administer IV calcium and magnesium. There is low risk for hypercalcemia or hypermagnesemia with this approach.
- The eye is highly susceptible to HF exposure. The most important therapy is immediate irrigation. Contacts should be removed, and eyes should be irrigated with 1 liter of water or preferably normal saline. This can be administered using a nasal cannula setup or Morgan lenses for eye irrigation. A 1% calcium gluconate solution for follow up irrigation has been suggested in some articles, but this treatment is controversial and may cause worsening irritation. Prompt ophthalmological consultation should occur.
The tactical medical provider should remain alert for the possibility of HF exposure. Consider beforehand having access to a water supply for decontamination and carrying 10% calcium gluconate that can be readily mixed in the field. Ten percent calcium gluconate comes in 10 ml, 50 ml and 100 ml plastic vials and does not require refrigeration. Normal saline and water-soluble lubricant should be carried so the provider can mix nebulized and topical calcium treatments as needed.
Calcium gluconate 10%
75 ml water soluble lubricant
4.5 ml NS
If possible, mass decontamination with copious water should be performed on all victims as soon as possible. If the HF exposure occurs in or near a house, the fastest decontamination treatment may be to guide the exposed person into a bathroom for clothing removal and an extended shower of at least 20 minutes. Other options for field decontamination include having a 25-foot hose, an attachment for converting a standard fire hydrant to a garden hose, and a wrench for turning on the water. These items can be kept in a SWAT vehicle for retrieval if a hazardous exposure is suspected.
Patients with immediate severe pain after exposure are likely to have had exposure to higher concentrations of HF and may require more antidotes. Activating Hazmat teams to stage nearby for decontamination may be an important consideration, especially in the setting of a multiple exposures.
Emergency Department Treatment Principles:
- If not already performed in the field, decontaminate as above.
- Consider chemical injury to the nails. Fluoride ions readily pass through the nail plate and cause significant damage to the subungual tissues and could lead to systemic absorption; however, fingernails and toenails block irrigation and calcium gluconate from reaching the underlying tissue. Removal or trephination of the fingernail may be required to facilitate application of calcium gel to the underlying tissue.
- Clinical evidence of hypocalcemia is often absent; therefore, patients with HF exposure must be placed on cardiac monitoring and evaluated for prolonged QT interval and arrhythmias with electrocardiogram (12).
- When severe systemic toxicity is suspected, parenteral calcium and magnesium should be given even before the serum levels are determined. As mentioned, iatrogenic hypercalcemia or hypermagnesemia in this setting is rare, since total body stores of these ions are often severely depleted.
- Ionized calcium, magnesium and potassium must be frequently measured in cases of systemic toxicity. Other labs to consider include venous or arterial blood gas monitoring, kidney function and liver function.
- Proven hypocalcemia requires calcium gluconate infusion parenterally and frequent (hourly) serum calcium monitoring (15).
- Treat hyperkalemia as per usual.
- In systemic HF toxicity it is beneficial to maintain normal acid base status. In patients with metabolic acidosis, alkalization of urine by administering parenteral sodium bicarbonate improves excretion of fluoride and may help normalize acid-base status.
- Consider hemodialysis to reduce both fluoride and potassium levels, and to treat persistent hypocalcemia despite calcium infusion, especially in patients with decreased renal function.
- If ingestion occurred recently, gastric lavage via NG tube may be of benefit. Risk of gastric or esophageal perforation must be balanced against the risk of death from systemic absorption. The provider placing the NG is at risk of dermal or inhalational exposure related to the procedure so proper PPE is a must.
- Local calcium gluconate injections have been widely adopted for use on moderate to severe HF burns as it has been shown to reliably reduce pain (16). Indications include a central hard grey area with surrounding erythema and throbbing severe pain despite management with irrigation and gel. Infiltration is thought to be unnecessary for burns with HF concentrations ≤20%. A 27-gauge needle can be used to inject a 5% to 10% calcium gluconate solution into subcutaneous tissue beneath the burn. It is recommended to inject no more than 0.5 mL/cm2of burn surface area, as infiltration has been associated with increased compartment pressure and necrosis. Compartments should be monitored closely after injection. Edelman et al were first to describe this and set a limit of 0.5 mL per phalanx with repeated injections preferred (17).
- For patients with severe HF burns with unrelenting pain despite aggressive calcium gel topical therapy, typically of the digits or other poorly distensible areas that will not tolerate intradermal injection, intra-arterial calcium infusion has been used; this management technique may be associated with complications including arterial spasm and bleeding, ulnar nerve palsy secondary to immobilization, median nerve palsies secondary to hematomas, and carpal tunnel syndrome (2). It is traditionally used for digital burns of the hand but has also been described for the face and lower extremities. The technique was first described in 1978, using angiography to guide the route of infusion to the radial, ulnar, or brachial artery and then infusing 50 mL of 4% calcium gluconate given over a 4-hour period (18). This cycle was repeated every 12 hours until the patient was free from pain. More recently, an artery such as the radial artery, proximal to the burns is cannulated. Placement of the cannula should be confirmed by angiography, although an arterial line with good wave form placed on first attempt without any difficulty could be assumed to be usable as well. 10 ml of 10% calcium gluconate is added to 40 mL of either D5W or NS (resulting in a 2% calcium gluconate solution) and infused intraarterially over 4 hours. This treatment may need repeated for recurrent pain (19).
Hydrofluoric acid chemical burns are an important consideration in patients seeking medical treatment with signs of chemical injury following riots and violent protests. The hallmark physical exam finding is “pain out of proportion to exam” though the patient may be completely asymptomatic initially. Serious systemic toxicity can occur with even small cutaneous exposures. Alongside the normal field medical assessment and treatments, every known or suspected exposure should have immediate and thorough skin irrigation with water for 20-30 minutes followed by application of calcium gluconate topical gel. Providers should consider inhaled calcium gluconate for patients with signs of inhalational exposure. Ingestions should be treated with decontamination and dilution by drinking copious water and antacids. Eye exposure should be treated with immediate irrigation. Patients with signs of toxicity should be empirically treated with IV calcium gluconate and magnesium pending lab evaluation. Patients require prompt ECG and cardiac monitoring for dysrhythmias and prolonged QT interval. Once lab is available, serum electrolyte levels, liver, and renal function, and blood gas should be obtained urgently, and electrolyte levels should be repeated hourly at a minimum.
We would like to thank and acknowledge the contributions of Amber Adams, PharmD and Courtney Olesky, PharmD in describing the packaging, handling, and other aspects in the field use of calcium gluconate.
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Jett MacPherson, MS4
Marshall University Joan C. Edwards School of Medicine
Cabell Huntington Hospital