Ahmed Zedan MDa, Sabry Omar MDa, Mahmoud Fenire MDa
Correspondence to Ahmed Zedan MD
Email: ahmed.zedan@ttuhsc.edu
SWRCCC : 2014;2.(5):34-38
doi: 10.12746/swrccc2014.0205.060
Drugs, including those used during diagnostic procedures, can have adverse effects and potentially serious side-effects, especially in complicated patients with significant comorbidity. Benzocaine is frequently used as an oropharyngeal anesthetic agent during bronchoscopy, transesophageal echocardiography, and upper GI endoscopy and can cause methemoglobinemia, a potentially life-threatening event if not diagnosed and treated quickly. Co-oximetry is the gold standard for the diagnosis of methemoglobinemia and can quantitate blood levels, which in turn correlate with the clinical presentation and the urgency for treatment. Methylene blue is the treatment of choice for methemoglobinemia. In this case report we discuss the pathophysiology, the clinical presentation, the diagnosis, and the treatment of benzocaine-induced methemoglobinemia.
Keywords: methemoglobinemia, methylene blue, tissue hypoxia, benzocaine
...................................................................................................................................................................................................................................................................................................................................
Methemoglobinemia (hemoglobin with oxidized iron, Fe+++) is a rare cause of central cyanosis that can be life threatening. Under normal physiologic conditions, methemoglobin has a half-life of 55 minutes, and levels are below 2%.1,2 Methemoglobinemia can be either acquired or congenital. Acquired methemoglobinemia occurs when the rate of methemoglobin formation exceeds the rate of its reduction and is often caused by pharmacologic agents. Dapsone is used to treat infectious diseases such as pneumocystis and some autoimmune disorders and can cause methemoglobinemia. The topical anesthetic benzocaine is commonly used in some procedures, like bronchoscopy or transesophageal echocardiogram, and can also cause methemoglobinemia. Therefore, all health care providers, especially those participating in these procedures, should know the association between routine procedures and methemoglobinemia for early recognition and treatment. In this report we discuss a case of acquired drug-induced methemoglobinemia associated with the use of benzocaine for transesophageal echocardiography (TEE).
A 42-year-old man with a past medical history of type 2 diabetes mellitus, hypertension, drug abuse, and left below-knee amputation presented to the emergency department with his right leg “dragging” and altered speech that started a few hours before his arrival. An immediate CT scan of the brain didn’t show any evidence of intracranial pathology. A MRI showed an acute nonhemorrhagic left anterior cerebral artery infarct and acute nonhemorrhagic bilateral occipital infarcts. On physical examination his temperature was 98.5°F, blood pressure 173/79 mmHg, pulse rate 73 beats per minute, and respiratory rate 16 breaths per minute. His heart and lung examinations were within normal limits, and his oxygen saturation was 97% on room air. Laboratory finding showed WBC 7.5 k/µL, hemoglobin 13.8 gm/dl, normal troponin, and brain natriuretic peptide 750 pg/ml (nl< 124 pg/ml). His 12-lead electrocardiogram and chest x-ray were within normal limits. The patient was admitted for treatment and started on simvastatin, aspirin, Procardia XL, hydrochlorothiazide, and enoxaparin. His work-up for an acute stroke included transesophageal echocardiography. Before this procedure, his vital signs were: temperature 98 °F, blood pressure 145/75 mmHg, pulse 78 beats per minute, and respiratory rate 15 breaths per minute. During the procedure benzocaine 20% spray was used for oropharyngeal anesthesia. Oxygen saturations by pulse oximetry before, after, and during the procedure were 97% on 2L oxygen nasal cannula. The echocardiogram did not show any evidence of cardiac structural abnormalities with a normal ejection fraction (60-64%). An hour after the procedure the patient developed central cyanosis; his oxygen saturation was 85% by pulse oximetry. His blood pressure was 152/77 mmHg, heart rate 105 beats per minute, and respiratory rate 32 breaths per minute. His cardiovascular and chest examination was within normal limits. The patient felt uncomfortable and lethargic. Oxygen was administered with a non-rebreathing face mask initially at 10 L/minute and then at 15 L/minute when the cyanosis did not resolve. A chest x-ray was normal, an electrocardiogram showed sinus tachycardia, and a chest CT with PE protocol showed no evidence of pulmonary emboli. ABG results included pH 7.45, PCO2 42 mmHg, and PO2 282 mmHg. Troponin, CK, and CKMB levels were within normal limits. Methemoglobinemia was suspected; co-oximetry revealed a methemoglobin level of 37% (normal 0.6–2.5%). Methylene blue was started, and after eight hours his methemoglobin level decreased to 6.6 %. The patient's oxygen requirements decreased to 3 L/minute by nasal cannula. Within 12 hours, his cyanosis resolved. A repeat arterial blood gas the next morning demonstrated a methemoglobin level of 1.1% by co-oximetry.
Hemoglobin is a tetramer composed of alpha, beta, gamma, or delta chains. The most common form of hemoglobin in adults (HbA) consists of two α and two β chains. Each hemoglobin chain is formed by a globin polypeptide linked to a heme group, which is formed by a complex of a protoporphyrin IX ring and one atom of ferrous iron (Fe+2). Thus, each Hb molecule has four atoms of iron. Each ferrous iron can reversibly link one O2 molecule, and four molecules of O2 are transported by each hemoglobin molecule.
Hemoglobin is constantly being oxidized, but intrinsic reducing systems maintain the levels of methemoglobin under 2%. NADH-methemoglobin reductase (NADH-NR), a system with two enzymes- cytochrome B5 and cytochrome B5-reductase, maintains endogenous reduction of methemoglobinemia and accounts for 99% of the reducing activity. NADH-methemoglobin reductase transfers one electron from NADH to methemoglobin, changing it into reduced hemoglobin. Other systems also help maintain low levels of methemoglobin, and these include ascorbic acid, glutathione, and NADPH dehydrogenase. Under normal conditions these pathways are less significant but become important when NADH-MR is disrupted. When Fe+2 is oxidized to ferric iron (Fe+3), it cannot bind oxygen. Ferric iron also causes an allosteric change in the heme portion of partially oxidized hemoglobin and increases O2 affinity. This methemoglobin shifts the dissociation curve of partially oxidized hemoglobin to the left and reduces the release of O2 in the tissues leading to tissue hypoxia.
Hereditary methemoglobinemia is rare. The most common cause of congenital methemoglobinemia is cytochrome b5 reductase deficiency (type Ib5R) which is endemic in certain Native American tribes. Most cases of methemoglobinemia are acquired and occur after exposure to drugs or toxins. Topical benzocaine, an oropharyngeal anesthetic medication, is probably the most common cause of acquired methemoglobinemia. A study of 886 patients undergoing TEE reported that methemoglobinelevation occurred in four patients (0.115%).3 Ash-Bernal reviewed 138 cases of acquired methemoglobinemia; 56 cases were taking dapsone for the prevention or treatment of an infection caused by Pneumocystis jiroveci. The next group comprised patients undergoing surgical procedures and diagnostic investigations, such as cardiac catheterization. The highest methemoglobin concentrations were observed in five patients in whom a 20% benzocaine spray had been used. One patient subsequently died, and three others required long-term treatment.4 At the Mayo Clinic during a six and one-half year period, 28,478 patients underwent TEEs; 19 cases had methemoglobinemia with a mean methemoglobin level of 32% ± 15%. Eighteen patients received methylene blue (1.3 ± 0.4 mg/kg of body weight) with resolution of symptoms and signs. One patient resolved spontaneously.5
Clinical manifestations of methemoglobinemia reflect the reduction in O2-carrying capacity and associated tissue hypoxia. The presentation of methemoglobinemia depends on both the methemoglobin concentrations and patient co-morbidity. Methemoglobin concentrations under 15% cause only a grayish pigmentation of the skin. Above 12% to 15%, the blood is a brown chocolate color, and patients have central cyanosis unresponsive to the administration of O2. With methemoglobin levels above 20% to 30% neurological (dizziness, headache, anxiety, somnolence, and seizures) and cardiovascular symptoms (dyspnea, low cardiac output symptoms) start to appear. As levels of methemoglobin increase, the patient may have a reduced level of consciousness, respiratory depression, shock, and death. Levels of methemoglobin above 70% are usually fatal. Anemia makes patients more sensitive to methemoglobinemia by reducing the functional stores of hemoglobin.
Table: Clinical presentation of methemoglobinemia based on methemoglobin level in blood.6
Methemoglobinemia should be suspected in patients with central cyanosis, tachypnea, and low O2 saturations on pulse oximetry, especially if not responding to 100% oxygen. Other common causes like cardiopulmonary disorders also need to be considered. Arterial blood gases with co-oximetry are the gold standard for the diagnosis of methemoglobinemia and measure the concentration of different types of hemoglobin in blood through spectrophotometry using different wavelengths. This technology is based on the Lambert-Beer law that correlates the concentration of a dissolved substance with the intensity of the light transmitted through a solution. Other ways to confirm the diagnosis include apositive Kronenberg test result or confirmation of the oxygen saturation gap.6
The treatment of methemoglobinemia should be guided by the severity of the disorder. Blood levels of methemoglobin represent a secondary parameter in the decision about treatment. Usually, the symptoms are mild. In those cases, treatment consists of removing the inducing agent, administration of high-flow O2, observation, and periodic co-oximetry assessment.7 After discontinuation of the causative agent, the methemoglobin level usually returns to baseline levels within 36 hours. The use of supplementary O2 increases plasma levels of dissolved O2 and increases diffusion and oxygen delivery. With significant clinical manifestations (e.g., dizziness, headache, anxiety, dyspnea, symptoms of low cardiac output, somnolence, and seizures), methylene blue should be started as an antidote. Some authors suggest that methylene blue should be used with methemoglobin level above 30% regardless of symptoms. This is especially recommended when the patient is unconscious (e.g., head trauma, deep sedation, or general anesthesia). Methylene blue is given intravenously in a dose of 1 to 2 mg/kg over five minutes. During its use, the alternative enzymatic system (NADPH methemoglobin reductase) becomes fundamental in the reduction of methemoglobin. Methylene blue activates NADPH methemoglobin reductase which reduces methylene blue to methylene leucoblue, which transforms methemoglobin to reduced hemoglobin by a non-enzymatic mechanism.8,9 Additional doses can be administered every hour, if necessary, up to a maximum total dose of 7 mg/kg. If the dose exceeds 15 mg/kg, it can cause direct damage of red blood cells and hemolysis with Heinz body formation.
Methylene blue should not be administered to patients with known glucose 6-phosphate dehydrogenase (G6PD) deficiency, because methylene blue depends upon NADPH generated by G6PD in the reduction process of methemoglobin. As a result, this medication may not only be ineffective but is also potentially dangerous, since methylene blue has an oxidant potential that may induce hemolysis in G6PD deficient subjects.10. The levels of methemoglobin should fall significantly 30 to 60 minutes after the first dose. This drug should be administered carefully in patients with renal failure, since both methylene blue and leucoblue are slowly excreted by the kidneys. During treatment, the urine has a bluish tint. The same occurs, in varying degrees, to the skin and mucous membranes, hindering the interpretation of cyanosis after the treatment. Other treatments for methemoglobinemia include ascorbic acid with the intravenous administration of 300 to 1,000 mg daily in selected cases of non-severe NADH-MR deficiency. Blood transfusion or exchange transfusion may be helpful in patients who are in shock. Hyperbaric oxygen has been used with anecdotal success in severe cases.11
Methemoglobinemia is an uncommon cause of central cyanosis that can be a life threatening condition if not considered in the differential diagnosis and work-up of patients who are refractory to oxygen administration. Benzocaine, a commonly used atopical anesthetic, and dapsone can cause methemoglobinemia as rare life threatening side effect. Methylene blue should be available in all areas where benzocaine is used to allow rapid and prompt management of this condition.
...................................................................................................................................................................................................................................................................................................................................