The mystery of ‘saturation gap’: a case of dapsone-induced methaemoglobinemia in a pregnant mother with leprosy

Tang, Andy Sing Ong; Yeo, Siaw Tze; Teh, Yeon Chiat; Kho, Wee Meng; Chew, Lee Ping; Muniandy, Pubalan

doi:10.1093/omcr/omy111

Cited by 5 publications

(7 citation statements)

References 14 publications

(14 reference statements)

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“… 19 – 22 It has been reported that methemoglobinemia can cause a discrepancy between the values of

measured by a conventional pulse oximeter and the actual arterial oxygen saturation (

) calculated by arterial blood gas measurement. 19 – 22 The values of

are not proportional to the actual

during methemoglobinemia, since elevated methemoglobin levels (up to 60%) force the

value to be around 85%, whereas

reaches

. 19 When methemoglobin is elevated, the

values measured by conventional pulse oximetry are inaccurate and can falsely diagnose the actual status of patients.…”

Section: Resultsmentioning

confidence: 99%

“… 19 However, when the level of methemoglobin is high, the result is unreliable, because the pulse oximeter readings remain stable. 19 – 22 CO-oximetry is a bench-top analysis method for the evaluation of methemoglobin, and it has been used as the traditional detection tool for methemoglobinemia. Although CO-oximetry can be used to monitor the response to treatment for methemoglobinemia, it is costly and requires an invasive procedure for collecting blood samples from patients.…”

Section: Introductionmentioning

confidence: 99%

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Transcutaneous monitoring of hemoglobin derivatives during methemoglobinemia in rats using spectral diffuse reflectance

2021

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. Significance: Untreated methemoglobinemia may cause severe hypoxemia and even death when methemoglobin levels in the blood stream exceed 70%. Although CO-oximetry can be used to monitor the response to treatment for methemoglobinemia, it is costly and requires an invasive procedure for collecting blood samples from patients. A pulse CO-oximeter with a contact probe can be used to continuously and non-invasively measure the percentage of methemoglobin, as well as the percutaneous oxygen saturation. In terms of the prevention of infectious diseases, however, it is desirable to monitor methemoglobin and oxygen saturation levels in a non-contact manner. Diffuse reflectance spectral imaging is promising as a non-contact, non-invasive, and cost-effective clinical diagnostic tool for methemoglobinemia. Aim: To demonstrate the feasibility of visible spectral diffuse reflectance for in vivo monitoring of hemoglobin derivatives and evaluating methemoglobin production and reduction as well as hypoxemia during methemoglobinemia in rats. Approach: A new imaging approach based on the multiple regression analysis aided by Monte Carlo simulations for light transport was developed to quantify methemoglobin, oxygenated hemoglobin, and deoxygenated hemoglobin using a hyperspectral imaging system. An in vivo experiment with rats exposed to sodium nitrite ( ) at different doses was performed to confirm the feasibility of the method for evaluating the dynamics of methemoglobin, oxygenated hemoglobin, and deoxygenated hemoglobin during methemoglobinemia. Systemic physiological parameters, including the percutaneous arterial oxygen saturation, heart rate (HR), and pulse distention, were measured by a commercially available pulse oximeter, and the results were compared to those obtained by the proposed method. Results: Both the methemoglobin concentration and methemoglobin saturation rapidly increased with a half-maximum time of . They reached their maximal values nearly 60 min after the administration of . Tissue oxygen saturation dramatically dropped to a minimum of , , , and on average for doses of 25, 37.5, 50, and 75 mg/kg, respectively. Changes in methemoglobin concentration and tissue oxygen saturation are indicative of the temporary production of methemoglobin and severe hypoxemia during methemoglobinemia. Profound increases in the HR and pulse distention implied an elevated cardiac output caused by tachycardia and the resultant increase in peripheral blood volume to compensate for the hypoxia and hypoxemia during methemoglobinemia. This was in agreement with the time course of the peripheral hemoglobin volume concentration obtained by the proposed method. Conclusions: The proposed method is capable of the in vivo non-...

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“… 19 – 22 It has been reported that methemoglobinemia can cause a discrepancy between the values of

measured by a conventional pulse oximeter and the actual arterial oxygen saturation (

) calculated by arterial blood gas measurement. 19 – 22 The values of

are not proportional to the actual

during methemoglobinemia, since elevated methemoglobin levels (up to 60%) force the

value to be around 85%, whereas

reaches

. 19 When methemoglobin is elevated, the

values measured by conventional pulse oximetry are inaccurate and can falsely diagnose the actual status of patients.…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Transcutaneous monitoring of hemoglobin derivatives during methemoglobinemia in rats using spectral diffuse reflectance

2021

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“…Methemoglobin is an aberrant form of hemoglobin arising from oxidation of heme iron to the ferric (Fe 3+ ) form, resulting in a left shift in the oxygen saturation curve [ 1 ]. Hemolytic anemia may follow drug-induced methemoglobinemia, especially with exposure to dapsone and sulfonamides [ 2 ]. Clinicians should have a high index of suspicion and be able to recognize methemoglobinemia as an adverse effect attributable to dapsone use, particularly when patients present with cyanosis and hypoxemia of unclear etiology and there is a saturation gap (ie, a difference between oxygen saturation measured by pulse oximetry and arterial blood gas analysis) [ 2 ].…”

Section: Discussionmentioning

confidence: 99%

“…Hemolytic anemia may follow drug-induced methemoglobinemia, especially with exposure to dapsone and sulfonamides [ 2 ]. Clinicians should have a high index of suspicion and be able to recognize methemoglobinemia as an adverse effect attributable to dapsone use, particularly when patients present with cyanosis and hypoxemia of unclear etiology and there is a saturation gap (ie, a difference between oxygen saturation measured by pulse oximetry and arterial blood gas analysis) [ 2 ]. Our patient demonstrated oxygen-resistant cyanosis with a saturation gap of 37%.…”

Section: Discussionmentioning

confidence: 99%

Challenges in Managing a Lepromatous Leprosy Patient Complicated with Melioidosis Infection, Dapsone-Induced Methemoglobinemia, Hemolytic Anemia, and Lepra Reaction

et al. 2021

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Patient: Female, 22-year-old Final Diagnosis: Lepromatous leprosy co-infected with melioidosis • complicated by dapsone-induced methaemoglobinaemia and type 2 lepra reaction Symptoms: Cyanosis • fever • jaundice • pallor • skin rash Medication: — Clinical Procedure: — Specialty: Dermatology • Hematology • Infectious Diseases • General and Internal Medicine • Microbiology and Virology Objective: Unusual clinical course Background: Leprosy is an infection caused by Mycobacterium leprae . An extensive literature search did not reveal many reports of melioidosis in association with leprosy. Case Report: A 22-year-old woman, who was diagnosed with multibacillary leprosy, developed dapsone-induced methemoglobinemia and hemolytic anemia, complicated by melioidosis. Methemoglobinemia was treated with methylene blue and vitamin C. Two weeks of ceftazidime was initiated to treat melioidosis, and the patient was discharged on amoxicillin/clavulanic acid and doxycycline as melioidosis eradication therapy. However, she developed drug-induced hypersensitivity. Trimethoprim/sulfamethoxazole, as an alternative treatment for melioidosis eradication, was commenced and was successfully completed for 12 weeks. During the fifth month of multidrug therapy, the patient developed type II lepra reaction with erythema nodosum leprosum reaction, which was treated with prednisolone. Leprosy treatment continued with clofazimine and ofloxacin, and complete resolution of skin lesions occurred after 12 months of therapy. Conclusions: Our case highlighted the challenges posed in managing a patient with multibacillary leprosy with multiple complications. Clinicians should be aware that dapsone-induced methemoglobinemia and hemolysis might complicate the treatment of leprosy. Our case also highlighted the safety and efficacy of combining ofloxacin and clofazimine as a leprosy treatment regimen in addition to gradual steroid dose titration in the presence of type II lepra reaction.

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“…An abnormal level of methemoglobin (methemoglobinemia) may result from congenital enzyme deficiencies [9,19] or exposure to certain chemicals and medications turning hemoglobin into a dysfunctional form of hemoglobin [20][21][22][23][24]. These chemical agents include drugs used in hospitals and health care settings, such as some local anesthetics (e.g., benzocaine and lidocaine [20][21][22]) and antibiotics (e.g., dapsone [23]), as well as nitrates and nitrites present in fertilizers that may contaminate food and water supplies [24,25]. The initial symptoms appear as a bluish discoloration of the skin when the methemoglobin level is at least 10-20% of the total hemoglobin .…”

Section: Introductionmentioning

confidence: 99%

In Vivo Transcutaneous Monitoring of Hemoglobin Derivatives Using a Red-Green-Blue Camera-Based Spectral Imaging Technique

Khatun

Aizu

Nishidate

2021

IJMS

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Cyanosis is a pathological condition that is characterized by a bluish discoloration of the skin or mucous membranes. It may result from a number of medical conditions, including disorders of the respiratory system and central nervous system, cardiovascular diseases, peripheral vascular diseases, deep vein thrombosis, and regional ischemia. Cyanosis can also be elicited from methemoglobin. Therefore, a simple, rapid, and simultaneous monitoring of changes in oxygenated hemoglobin and deoxygenated hemoglobin is useful for protective strategies against organ ischemic injury. We previously developed a red-green-blue camera-based spectral imaging method for the measurements of melanin concentration, oxygenated hemoglobin concentration (CHbO), deoxygenated hemoglobin concentration (CHbR), total hemoglobin concentration (CHbT) and tissue oxygen saturation (StO2) in skin tissues. We leveraged this approach in this study and extended it to the simultaneous quantifications of methemoglobin concentration (CmetHb), CHbO, CHbR, and StO2. The aim of the study was to confirm the feasibility of the method to monitor CmetHb, CHbO, CHbR, CHbT, and StO2. We performed in vivo experiments using rat dorsal skin during methemoglobinemia induced by the administration of sodium nitrite (NaNO2) and changing the fraction of inspired oxygen (FiO2), including normoxia, hypoxia, and anoxia. Spectral diffuse reflectance images were estimated from an RGB image by the Wiener estimation method. Multiple regression analysis based on Monte Carlo simulations of light transport was used to estimate CHbO, CHbR, CmetHb, CHbT, and StO2. CmetHb rapidly increased with a half-maximum time of less than 30 min and reached maximal values nearly 60 min after the administration of NaNO2, whereas StO2 dramatically dropped after the administration of NaNO2, indicating the temporary production of methemoglobin and severe hypoxemia during methemoglobinemia. Time courses of CHbT and StO2, while changing the FiO2, coincided with well-known physiological responses to hyperoxia, normoxia, and hypoxia. The results indicated the potential of this method to evaluate changes in skin hemodynamics due to loss of tissue viability and vitality.

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The mystery of ‘saturation gap’: a case of dapsone-induced methaemoglobinemia in a pregnant mother with leprosy

Cited by 5 publications

References 14 publications

Transcutaneous monitoring of hemoglobin derivatives during methemoglobinemia in rats using spectral diffuse reflectance

Transcutaneous monitoring of hemoglobin derivatives during methemoglobinemia in rats using spectral diffuse reflectance

Challenges in Managing a Lepromatous Leprosy Patient Complicated with Melioidosis Infection, Dapsone-Induced Methemoglobinemia, Hemolytic Anemia, and Lepra Reaction

In Vivo Transcutaneous Monitoring of Hemoglobin Derivatives Using a Red-Green-Blue Camera-Based Spectral Imaging Technique

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