SGLT-2 inhibitor associated euglycaemic diabetic ketoacidosis in an orthopaedic trauma patient

  1. Duncan Taylor Ritchie 1 , 2 and
  2. James Dixon 1
  1. 1 Department of Trauma and Orthopaedic Surgery, NHS Grampian, Aberdeen, UK
  2. 2 School of Medicine Medical Sciences and Nutrition, University of Aberdeen, Aberdeen, UK
  1. Correspondence to Dr Duncan Taylor Ritchie; duncan.ritchie@nhs.scot

Publication history

Accepted:01 Sep 2022
First published:16 Sep 2022
Online issue publication:16 Sep 2022

Case reports

Case reports are not necessarily evidence-based in the same way that the other content on BMJ Best Practice is. They should not be relied on to guide clinical practice. Please check the date of publication.

Abstract

Euglycaemic diabetic ketoacidosis is a serious but rare adverse effect of treatment with sodium-glucose cotransporter-2 (SGLT-2) inhibitors. A man in his 60s with type 2 diabetes mellitus underwent total hip replacement for an intracapsular neck of femur fracture. His SGLT-2 inhibitor was continued perioperatively and blood glucose levels were normal throughout the admission. A diagnosis of severe euglycaemic diabetic ketoacidosis was made in the operating theatre which required treatment in a critical care unit. This resulted in increased morbidity due to decreased postoperative mobilisation and a new requirement for subcutaneous insulin. This case highlights the need for withholding SGLT-2 inhibitors in patients admitted for emergency surgery and a need for regular ketone monitoring in these patients, even in the context of normoglycaemia.

Background

Diabetic ketoacidosis (DKA) is a serious complication of diabetes mellitus. Admission to hospital for DKA has an incidence of 35.84 per 1000 person-years.1 The diagnostic criteria for DKA according to the Joint British Diabetes Societies for Inpatient Care (JBDS-IC) is a triad of blood glucose >11 mmol/L or known diabetes, blood ketone concentration >3 mmol/L and bicarbonate concentration of <15 mmol/L and/or venous pH <7.3.2 The classification of acidosis or the calculation of the anion-gap does not feature as part of the formal diagnosis of DKA. However, DKA would result in metabolic acidosis with raised anion-gap.3 In patients with metabolic acidosis with raised anion-gap, consideration should be given to DKA as a possible cause. Inpatient diabetic protocols, such as those at our own centre, typically do not include regular ketone monitoring. In our centre, diabetic patients have regular monitoring of capillary blood glucose levels only, with hyperglycaemia (>14 mmol/L) triggering a measurement of ketones. This is generally appropriate for type 1 diabetic patients for whom DKA is associated with insulin deficiency and therefore marked hyperglycaemia. In some patients, however, DKA can occur in the context of normal blood glucose levels, known as euglycaemic DKA (EuDKA). This is a rare feature associated with treatment with sodium-glucose cotransporter-2 (SGLT-2) inhibitors. SGLT-2 inhibitors decrease insulin secretion and increase glucagon levels. This increases the glucagon-insulin ratio which leads to increased gluconeogenesis, lipolysis and ketogenesis. SGLT-2 inhibitors reduce renal reabsorption of glucose via inhibition of SGLT-2 in the proximal tubules leading to glycosuria and reduction in blood glucose level. This combination of pharmacodynamics can lead to the potential for ketosis (and subsequent ketoacidosis) in the absence of hyperglycaemia; however, the exact mechanism has not been fully established.4 5 Certain triggering events can increase the risk of development of DKA, namely conditions leading to restricted food intake or severe dehydration, sudden reduction in insulin, increased insulin requirements due to acute illness, alcohol abuse and surgery.6 In this report, we describe a case of a patient with type 2 diabetes mellitus managed with an SGLT-2 inhibitor who during an emergency orthopaedic procedure was found to be in severe EuDKA. In this case, a traditional procedure for monitoring diabetic patients led to delayed diagnosis and subsequent morbidity from which there are important learning points.

Case presentation

A man in his early 60s with a history of type 2 diabetes mellitus, knee osteoarthritis and cervicalgia presented with left hip pain following a fall tripping over a kerb while walking his dog. He was unable to weight-bear postinjury and was assisted at home by his wife. He was positioned in a recliner chair at home where he stayed for 30 hours before phoning an ambulance. On examination, he was tender over the left hip and his left leg was shortened and externally rotated. Plain radiographs taken on admission demonstrated a left intracapsular neck of femur fracture.

His preadmission regular medications are displayed in table 1. These medications were continued during the perioperative period, with the exception of glimepiride which was withheld on the morning of surgery in accordance with local guidance in use at the time.

Table 1

Preadmission regular medications

Table 1

Preadmission regular medications

Despite the patient’s comorbidities, his preinjury function was high, mobilising with no walking aids and being active outdoors regularly. Therefore, it was planned to perform a total hip replacement. On day 2 of admission, he was fasted in anticipation of going to the emergency operating theatre; however, the procedure was cancelled due to theatre pressures, and he was given oral food and drink early evening. His procedure was cancelled again on day 3 after fasting and he was operated on day 4. Over this period, he slept more than usual. He also had a new oxygen requirement of 3 L/min and tachycardia of 110 beats per minute. Chest radiograph and infection markers did not indicate an infectious cause. On admission, the patient was euglycaemic, with capillary blood glucose levels 4–11 throughout. On admission, his HbA1c was 103 mmol/mol indicating poor diabetic control. HbA1c 2 years prior to admission was 132 mmol/mol. The patient had no pre-existing diabetic retinopathy, neuropathy or chronic kidney disease. In theatre, a severe high anion-gap metabolic acidosis was discovered. A summary of admission and intraoperative blood results is displayed in table 2.

Table 2

Relevant blood results on admission and intraoperative

On admission Intraoperative
Sodium (mmol/L) 139 139
Potassium (mmol/L) 4.3 4.7
Chloride (mmol/L) 102 109
Bicarbonate (mmol/L) 17 9.2
pH 6.96
pCO2 (kPa) 5.45
pO2 (kPa) 13.8
Base excess −22
Blood glucose (mmol/L) 8.3 11.3
Lactate (mmol/L) 0.5
Ketones (mmol/L) 4.9

Differential diagnosis

EuDKA: most likely diagnosis as the JBDS-IC criteria are met. He is (1) a known diabetic with (2) elevated ketones and (3) severe high anion-gap metabolic acidosis.

Starvation ketoacidosis: this is possible given repeated fasting for theatre; however, food was consumed each day. Starvation ketoacidosis usually causes mild ketoacidosis which makes this diagnosis less likely.7

Alcoholic ketoacidosis: unlikely given no reported history of alcohol excess.

Lactic acidosis: excluded by normal lactate level.

Treatment

DKA is a medical emergency and treatment was initiated as soon as possible after the initial diagnosis was made in the anaesthetic room. This followed the local DKA management pathway involving intravenous insulin and 0.9% sodium chloride. As this patient was euglycaemic, 10% glucose + 20 mmol potassium chloride infusion was also started to prevent iatrogenic hypoglycaemia and hypokalaemia.

Repeat blood gases showed an improvement in pH from 6.9 to 7.01 after initial fluid administration. A multiprofessional decision was taken to continue with the operation as the patient was already anaesthetised and had suffered significant delays to the theatre. He underwent total hip arthroplasty without any surgical complications. Following the operation, the patient was admitted to the intensive care unit (ICU) for critical care management of his severe DKA. During the first 4 days postoperative he remained ketotic but eventually stabilised on variable-rate insulin. He was stepped down to the endocrine ward. He did not receive physiotherapy until postoperative day 4. He developed a urinary tract infection (UTI) and was found to have glucosuria, this was managed with oral antibiotics.

Outcome and follow-up

From an endocrine perspective, preoperatively his HbA1c was 103 mmol/mol. On discharge, he is now taking metformin 1 g two times per day and insulin (Levemir 16 units at night and Novorapid 8–12 units before meals) resultantly his glycaemic control prior to discharge was excellently controlled. At 3 months, the diabetologist described a ‘massive overhaul of diet and lifestyle’. The HbA1c had fallen to 64 mmol/mol from 103 mmol/mol and Body Mass Index 34.2 from 37.3. Overall, in future this new regimen may lead to improved diabetic control. From a quality-of-life perspective, he now must inform the Driver and Vehicle Licensing Agency and modify his life around his insulin use.

From an orthopaedic perspective, at the time of discharge, he required a Zimmer frame to mobilise. Prior to his fall, he required no walking aids apart from occasionally one stick for long distances. At 4 months, he was mobilising with one walking stick indoors and outdoors, managing short distances only.

Discussion

The case literature describes two similar previous cases in orthopaedic trauma patients. One in a patient with L1 vertebral, left ulnar and right radius fractures8 and another in a patient with a femoral diaphyseal fracture.9 To our knowledge, this is the first case describing EuDKA associated with SGLT-2 inhibitor use in a patient undergoing surgical fixation of a hip fracture.

After hip fracture, significantly more patients require walking aids compared with prefracture state10 11 and they are more likely to be living in an institution after previously living independently.10 11 The requirement for walking aids is increased by lengthening postoperative immobility12–14 and a delay of >24 hours between the time of injury and surgical management.13–15 Comorbid diabetes mellitus is associated with a longer hospital stay, cardiac postoperative complications and the development of pressure ulcers16 but not independently associated with poorer long-term mobility.16 Diabetic patients undergoing hip fracture surgery have higher mortality.17 National guidelines dictate diabetic patients should be operated first on the list, and a maximum of 6 hours fasting for theatre.18 In this case, the patient was delayed extensively and had prolonged periods of fasting. This demonstrates the importance of adhering to established guidelines and ensuring diabetic patients undergoing hip fracture surgery are prioritised to reduce the risk of increased morbidity and mortality.

Current guidance from the Scottish Standard of Care for Hip Fracture Patients and British Orthopaedic Association Standards recommend surgery for hip fractures take place within 36 hours,19 20 while the American Academy of Orthopaedic Surgeons recommend surgery within 24–48 hours.21 The National Institute for Health and Care Excellence recommend surgery take place either on the day or the day after injury.22 This is summarised in figure 1. There are multiple recognised factors that contribute to delays to surgical fixation. These include delayed diagnosis,23 delayed consent,23 24 lack of theatre time,23 25 26 delays to facilitate total hip replacement23 and the patient being medically unfit for surgery.23–25 27 Delays to surgery for hip fracture fixation are associated with both increased mortality28 and morbidity29 as summarised in table 3.

Figure 1

Summary of guidance of timing for surgical repair of hip fractures. Times shown are the maximum times recommended between admission and surgical repair.

Table 3

Outcomes affected by delay to surgical fixation of hip fractures beyond 48 hours

Outcome Effect of delay to surgery
Mortality 41% increased mortality at 30 days.28
Development of pressure ulcers Increased risk of development of pressure ulcers. Absolute risk of 11% for delayed surgery and 6% for non-delayed.29
Medical complications (including thromboembolism, myocardial infarction and pneumonia) Increased risk. Absolute risk of complications of 17% for delayed surgery compared with 8% for non-delayed.29

Ethics statements

Patient consent for publication

Footnotes

  • Twitter @duncanrit

  • Contributors DTR: planning, literature review, manuscript writing and editing. JD: planning and manuscript editing.

  • Funding The authors have not declared a specific grant for this research from any funding agency in the public, commercial or not-for-profit sectors.

  • Case reports provide a valuable learning resource for the scientific community and can indicate areas of interest for future research. They should not be used in isolation to guide treatment choices or public health policy.

  • Competing interests None declared.

  • Provenance and peer review Not commissioned; externally peer reviewed.

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