Journal of Geriatric Cardiology (2018) 15: 238240 ©2018 JGC All rights reserved; www.jgc301.com
Letter to the Editor
Open Access
Anterior myocardial pseudoinfarction in a patient with diabetic ketoacidosis Jose Ruiz-Morales1, Catarina Canha1, Farah Al-Saffar2, Saif Ibrahim3,* 1
Internal medicine department, University of Florida, Jacksonville, FL, USA Cardiology Department, Mayo Clinic, Scottsdale, AZ, USA 3 Cardiology Department, University of Florida, Jacksonville, FL, USA 2
J Geriatr Cardiol 2018; 15: 238240. doi:10.11909/j.issn.1671-5411.2018.03.007 Keywords: Anterior STEMI; DKA; Heart attack; Pseudoinfarction; STEMI
Diabetic ketoacidosis remains one of the most serious complications of diabetes mellitus. Among its precipitating factors is myocardial ischemia, responsible for 1% of the cases of diabetic ketoacidosis.[1] Diabetic ketoacidosis both with and without hyperkalemia has been reported to mimic a myocardial infarction pattern on ECG with ST segment elevation, described as pseudoinfarction pattern.[1–3] Thus, it is important to raise awareness among physicians, as subjecting patients to invasive medical management can be avoided. We present a case of a 47-year-old female with diabetic ketoacidosis and hyperkalemia with initial ECG findings of ST segment elevation, but an urgent left heart catheterization revealed non-obstructive coronary disease. A 47-year old female with diabetes mellitus type 2 presented to the hospital with a three-day course of polydipsia, nausea, vomiting and abdominal pain. The patient had been non-compliant with her insulin regimen for the past three days but otherwise history was unremarkable. Specifically, no history of cardiac disease or anginal symptoms were present. Initial assessment revealed a body temperature of 35.6 C, blood pressure of 128/62, regular pulse with rate of 124 bpm and respiratory rate of 28 breaths/min. Except for poor skin turgor and tenderness upon abdominal palpation, the remainder of the findings of the physical exam were unremarkable. An ECG (Figure1) demonstrated sinus rhythm with ST-segment elevation in leads V1–V3 concerning for anterior myocardial infarction. The patient underwent emergent left heart catheterization which demonstrated non-obstructive coronary artery disease. Left ventricular end-diastolic pressure concerning for severe dehydration and left vetriculogram noted preserved ejection fraction. During the procedure, laboratory data revealed a white blood cell count of 40.46 103 cells/µL, hemoglobin level of 13.3 g/dL and a platelet count of 539 103 platelets/µL. *
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Blood chemistry examination revealed a urea nitrogen value of 46 mg/dL, creatinine level of 2.04 mg/dL, creatinine kinase level of 140 U/L, CK-MB level of 5.7 ng/mL. Troponin I and Troponin T negative. Otherwise, she had a serum glucose level of 985 mg/dL, beta-hydroxybutyrate level > 45 mg/dL, sodium level of 118 mmol/L, potassium level of 6.7 mmol/L, bicarbonate 4 mmol/L, anion gap 40 mmol/L. The diagnosis of diabetic ketoacidosis was made, and the patient was transferred to the intensive care unit for medical management. She was administered Lactated Ringer’s solution and continuous insulin infusion (0.1 units/Kg/hr). One hour after starting the treatment for ketoacidosis, the following results were obtained: serum glucose 613 mg/dL, potassium 4.6, bicarbonate 5 mmol/L. The ECG was repeated (Figure 2), and it was observed that the ST segments were in isoelectric line. Cardiac enzymes remained negative, the patient never presented any cardiac complaint. She was transferred to a general medical ward and eventually discharged home. Hyperkalemia is frequently seen in patients with diabetic ketoacidosis even though the total body potassium is depleted, this is due to acidosis, insulin deficiency and renal impairment.[1] Hyperkalemia can cause several characteristic ECG abnormalities that have been well described. Initially, the T wave becomes tall, symmetrically peaked, and tented and there is occasional QT interval shortening. Reduction of P wave amplitude and eventual disappearance is also seen. Widening of the QRS complex with various forms of intraventricular conduction delay then occurs. Further progression of hyperkalemia leads to a sine wave appearance of the ECG and eventual asystole. Rarely, ST-segment elevation mimicking myocardial infarction, described as a “pseudoinfarction” pattern, is present.[3,4] The pseudoinfarction pattern has been reported mostly in association with hyperkalemia associated with Diabetic Ketoacidosis (DKA) as well as in patients with end stage
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Figure 1. ECG on presentation demonstrating ST elevations on anterior leads V1–V3.
Figure 2. ECG demonstrating normalization of ST changes after fluid and DKA management. DKA: Diabetic Ketoacidosis.
renal disease.[5] Furthermore, this abnormality is uncommon in hyperkalemia alone[4] and a case of pseudoinfarction in DKA with normokalemia has also been reported.[2] Which raises the question on whether hyperkalemia is solely responsible for this pattern or metabolic acidosis/other metabolic abnormalities are implicated in this finding. In addition, myocardial infarction occurs when the atheromatous process prevents blood flow through the coronary artery.[6] Furthermore, according to Poiseuille’s law, blood viscosity is inversely related to flow.[7] Therefore, if blood viscosity is elevated, this could reduce myocardial per-
fusion and consequently lead to the observed ST elevation noted on the ECG. This is of interest because blood viscosity seems to be increased in patients with diabetes mellitus. The reasons remain unclear but it is believed that the increase in osmolarity causes increased capillary permeability and, consequently, increased hematocrit and viscosity. It has also been suggested that the osmotic diuresis, consequence of hyperglycemia, could contribute to reduce plasma volume and increase hematocrit.[8] This case report illustrates an unusual reversible ECG finding in a patient with diabetic ketoacidosis, hyperkalemia
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Ruiz-Morales J, et al. Anterior myocardial pseudoinfarction in patient with diabetic ketoacidosis
and hyperosmolarity capable of mimicking a myocardial infarction (pseudoinfarction pattern). Because myocardial infarction may precipitate DKA and because many diabetic patients present with silent myocardial infarction, a ST segment elevation finding on ECG can prompt immediate and unnecessary actions. Therefore, it is important for the physician to be familiarized with cases such as this to avoid unnecessary drug treatment, coronary angiography and its attendant risks.
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References
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