|Dehydration may be severe in diabetic ketoacidosis, and intravenous fluids are usually needed as part of its treatment.|
|Symptoms||Vomiting, abdominal pain, deep gasping breathing, increased urination, confusion, a specific smell|
|Usual onset||Relatively rapid|
|Causes||Shortage of insulin|
|Risk factors||Usually type 1 diabetes, less often other types|
|Diagnostic method||High blood sugar, low blood pH, ketoacids|
|Similar conditions||Hyperosmolar nonketotic state, alcoholic ketoacidosis, uremia, salicylate toxicity|
|Treatment||Intravenous fluids, insulin, potassium|
|Frequency||4–25% of people with type 1 diabetes per year|
Diabetic ketoacidosis (DKA) is a potentially life-threatening complication of diabetes mellitus. Signs and symptoms may include vomiting, abdominal pain, deep gasping breathing, increased urination, weakness, confusion, and occasionally loss of consciousness. A person's breath may develop a specific smell. Onset of symptoms is usually rapid. In some cases people may not realize they previously had diabetes.
DKA happens most often in those with type 1 diabetes, but can also occur in those with other types of diabetes under certain circumstances. Triggers may include infection, not taking insulin correctly, stroke, and certain medications such as steroids. DKA results from a shortage of insulin; in response the body switches to burning fatty acids which produces acidic ketone bodies. DKA is typically diagnosed when testing finds high blood sugar, low blood pH, and ketoacids in either the blood or urine.
The primary treatment of DKA is with intravenous fluids and insulin. Depending on the severity, insulin may be given intravenously or by injection under the skin. Usually potassium is also needed to prevent the development of low blood potassium. Throughout treatment blood sugar and potassium levels should be regularly checked. Antibiotics may be required in those with an underlying infection. In those with severely low blood pH, sodium bicarbonate may be given; however, its use is of unclear benefit and typically not recommended.
Rates of DKA vary around the world. In the United Kingdom, about 4% of people with type 1 diabetes develop DKA each year, while in Malaysia the condition affects about 25% a year. DKA was first described in 1886 and, until the introduction of insulin therapy in the 1920s, it was almost universally fatal. The risk of death with adequate and timely treatment is currently around 1–4%. Up to 1% of children with DKA develop a complication known as cerebral edema.
Signs and symptoms
The symptoms of an episode of diabetic ketoacidosis usually evolve over a period of about 24 hours. Predominant symptoms are nausea and vomiting, pronounced thirst, excessive urine production and abdominal pain that may be severe. Those who measure their glucose levels themselves may notice hyperglycemia (high blood sugar levels). In severe DKA, breathing becomes labored and of a deep, gasping character (a state referred to as "Kussmaul respiration"). The abdomen may be tender to the point that an acute abdomen may be suspected, such as acute pancreatitis, appendicitis or gastrointestinal perforation. Coffee ground vomiting (vomiting of altered blood) occurs in a minority of people; this tends to originate from erosion of the esophagus. In severe DKA, there may be confusion, lethargy, stupor or even coma (a marked decrease in the level of consciousness).
On physical examination there is usually clinical evidence of dehydration, such as a dry mouth and decreased skin turgor. If the dehydration is profound enough to cause a decrease in the circulating blood volume, tachycardia (a fast heart rate) and low blood pressure may be observed. Often, a "ketotic" odor is present, which is often described as "fruity", often compared to the smell of pear drops whose scent is a ketone. If Kussmaul respiration is present, this is reflected in an increased respiratory rate.
Small children with DKA are relatively prone to cerebral edema (swelling of the brain tissue), which may cause headache, coma, loss of the pupillary light reflex, and progress to death. It occurs in 0.3–1.0% of children with DKA, and has been described in young adults, but is overall very rare in adults. It carries a 20–50% mortality.
DKA most frequently occurs in those who already have diabetes, but it may also be the first presentation in someone who had not previously been known to be diabetic. There is often a particular underlying problem that has led to the DKA episode; this may be intercurrent illness (pneumonia, influenza, gastroenteritis, a urinary tract infection), pregnancy, inadequate insulin administration (e.g. defective insulin pen device), myocardial infarction (heart attack), stroke or the use of cocaine. Young people with recurrent episodes of DKA may have an underlying eating disorder, or may be using insufficient insulin for fear that it will cause weight gain.
Diabetic ketoacidosis may occur in those previously known to have diabetes mellitus type 2 or in those who on further investigations turn out to have features of type 2 diabetes (e.g. obesity, strong family history); this is more common in African, African-American and Hispanic people. Their condition is then labeled "ketosis-prone type 2 diabetes".
Drugs in the gliflozin class (SGLT2 inhibitors), which are generally used for type 2 diabetes, have been associated with cases of diabetic ketoacidosis where the blood sugars are not significantly elevated ("euglycemic DKA"). This may be because they were being used in people with type 1 diabetes, but in those with type 2 diabetes it may be as a result of an increase in glucagon levels.
Diabetic ketoacidosis arises because of a lack of insulin in the body. The lack of insulin and corresponding elevation of glucagon leads to increased release of glucose by the liver (a process that is normally suppressed by insulin) from glycogen via glycogenolysis and also through gluconeogenesis. High glucose levels spill over into the urine, taking water and solutes (such as sodium and potassium) along with it in a process known as osmotic diuresis. This leads to polyuria, dehydration, and polydipsia. The absence of insulin also leads to the release of free fatty acids from adipose tissue (lipolysis), which are converted through a process called beta oxidation, again in the liver, into ketone bodies (acetoacetate and β-hydroxybutyrate). β-Hydroxybutyrate can serve as an energy source in the absence of insulin-mediated glucose delivery, and is a protective mechanism in case of starvation. The ketone bodies, however, have a low pKa and therefore turn the blood acidic (metabolic acidosis). The body initially buffers the change with the bicarbonate buffering system, but this system is quickly overwhelmed and other mechanisms must work to compensate for the acidosis. One such mechanism is hyperventilation to lower the blood carbon dioxide levels (a form of compensatory respiratory alkalosis). This hyperventilation, in its extreme form, may be observed as Kussmaul respiration.
In various situations such as infection, insulin demands rise but are not matched by the failing pancreas. Blood sugars rise, dehydration ensues, and resistance to the normal effects of insulin increases further by way of a vicious circle.
As a result of the above mechanisms, the average adult with DKA has a total body water shortage of about 6 liters (or 100 mL/kg), in addition to substantial shortages in sodium, potassium, chloride, phosphate, magnesium and calcium. Glucose levels usually exceed 13.8 mmol/L or 250 mg/dL.
DKA is common in type 1 diabetes as this form of diabetes is associated with an absolute lack of insulin production by the islets of Langerhans. In type 2 diabetes, insulin production is present but is insufficient to meet the body's requirements as a result of end-organ insulin resistance. Usually, these amounts of insulin are sufficient to suppress ketogenesis. If DKA occurs in someone with type 2 diabetes, their condition is called "ketosis-prone type 2 diabetes". The exact mechanism for this phenomenon is unclear, but there is evidence both of impaired insulin secretion and insulin action. Once the condition has been treated, insulin production resumes and often the person may be able to resume diet or tablet treatment as normally recommended in type 2 diabetes.
The clinical state of DKA is associated, in addition to the above, with the release of various counterregulatory hormones such as glucagon and adrenaline as well as cytokines, the latter of which leads to increased markers of inflammation, even in the absence of infection.
Cerebral edema, which is the most dangerous DKA complication, is probably the result of a number of factors. Some authorities suggest that it is the result from overvigorous fluid replacement, but the complication may develop before treatment has been commenced. It is more likely in those with more severe DKA, and in the first episode of DKA. Likely factors in the development of cerebral edema are dehydration, acidosis and low carbon dioxide levels; in addition, the increased level of inflammation and coagulation may, together with these factors, lead to decreased blood flow to parts of the brain, which then swells up once fluid replacement has been commenced. The swelling of brain tissue leads to raised intracranial pressure ultimately leading to death.
Diabetic ketoacidosis may be diagnosed when the combination of hyperglycemia (high blood sugars), ketones in the blood or on urinalysis and acidosis are demonstrated. In about 10% of cases the blood sugar is not significantly elevated ("euglycemic diabetic ketoacidosis").
Arterial blood gas measurement is usually performed to demonstrate the acidosis; this requires taking a blood sample from an artery. Subsequent measurements (to ensure treatment is effective), may be taken from a normal blood test taken from a vein, as there is little difference between the arterial and the venous pH. Ketones can be measured in the urine (acetoacetate) and blood (β-hydroxybutyrate). When compared with urine acetoacetate testing, capillary blood β-hydroxybutyrate determination can reduce the need of admission, shorten the duration of hospital admission and potentially reduce the costs of hospital care. At very high levels, capillary blood ketone measurement becomes imprecise.
In addition to the above, blood samples are usually taken to measure urea and creatinine (measures of kidney function, which may be impaired in DKA as a result of dehydration) and electrolytes. Furthermore, markers of infection (complete blood count, C-reactive protein) and acute pancreatitis (amylase and lipase) may be measured. Given the need to exclude infection, chest radiography and urinalysis are usually performed.
Diabetic ketoacidosis is distinguished from other diabetic emergencies by the presence of large amounts of ketones in blood and urine, and marked metabolic acidosis. Hyperosmolar hyperglycemic state (HHS, sometimes labeled "hyperosmolar non-ketotic state" or HONK) is much more common in type 2 diabetes and features increased plasma osmolarity (above 320 mosm/kg) due to profound dehydration and concentration of the blood; mild acidosis and ketonemia may occur in this state, but not to the extent observed in DKA. There is a degree of overlap between DKA and HHS, as in DKA the osmolarity may also be increased.
Ketoacidosis is not always the result of diabetes. It may also result from alcohol excess and from starvation; in both states the glucose level is normal or low. Metabolic acidosis may occur in people with diabetes for other reasons, such as poisoning with ethylene glycol or paraldehyde.
- Mild: blood pH mildly decreased to between 7.25 and 7.30 (normal 7.35–7.45); serum bicarbonate decreased to 15–18 mmol/l (normal above 20); the person is alert
- Moderate: pH 7.00–7.25, bicarbonate 10–15, mild drowsiness may be present
- Severe: pH below 7.00, bicarbonate below 10, stupor or coma may occur
A 2004 statement by the European Society for Paediatric Endocrinology and the Lawson Wilkins Pediatric Endocrine Society (for children) uses slightly different cutoffs, where mild DKA is defined by pH 7.20–7.30 (bicarbonate 10–15 mmol/l), moderate DKA by pH 7.1–7.2 (bicarbonate 5–10) and severe DKA by pH<7.1 (bicarbonate below 5).
Attacks of DKA can be prevented in those known to have diabetes to an extent by adherence to "sick day rules"; these are clear-cut instructions to person on how to treat themselves when unwell. Instructions include advice on how much extra insulin to take when sugar levels appear uncontrolled, an easily digestible diet rich in salt and carbohydrates, means to suppress fever and treat infection, and recommendations when to call for medical help.
People with diabetes can monitor their own ketone levels when unwell and seek help if they are elevated.
The main aims in the treatment of diabetic ketoacidosis are replacing the lost fluids and electrolytes while suppressing the high blood sugars and ketone production with insulin. Admission to an intensive care unit or similar high-dependency area or ward for close observation may be necessary.
The amount of fluid replaced depends on the estimated degree of dehydration. If dehydration is so severe as to cause shock (severely decreased blood pressure with insufficient blood supply to the body's organs), or a depressed level of consciousness, rapid infusion of saline (1 liter for adults, 10 ml/kg in repeated doses for children) is recommended to restore circulating volume. Slower rehydration based on calculated water and sodium shortage may be possible if the dehydration is moderate, and again saline is the recommended fluid. Very mild ketoacidosis with no associated vomiting and mild dehydration may be treated with oral rehydration and subcutaneous rather than intravenous insulin under observation for signs of deterioration.
A special but unusual consideration is cardiogenic shock, where the blood pressure is decreased not due to dehydration but due to inability of the heart to pump blood through the blood vessels. This situation requires ICU admission, monitoring of the central venous pressure (which requires the insertion of a central venous catheter in a large upper body vein), and the administration of medication that increases the heart pumping action and blood pressure.
Some guidelines recommend a bolus (initial large dose) of insulin of 0.1 unit of insulin per kilogram of body weight. This can be administered immediately after the potassium level is known to be higher than 3.3 mmol/l; if the level is any lower, administering insulin could lead to a dangerously low potassium level (see below). Other guidelines recommend delaying the initiation of insulin until fluids have been administered. It is possible to use rapid acting insulin analogs injections under the skin for mild or moderate cases.
In general, insulin is given at 0.1 unit/kg per hour to reduce the blood sugars and suppress ketone production. Guidelines differ as to which dose to use when blood sugar levels start falling; some recommend reducing the dose of insulin once glucose falls below 16.6 mmol/l (300 mg/dl) but other recommend infusing glucose in addition to saline to allow for ongoing infusion of higher doses of insulin.
Potassium levels can fluctuate severely during the treatment of DKA, because insulin decreases potassium levels in the blood by redistributing it into cells via increased sodium-potassium pump activity. A large part of the shifted extracellular potassium would have been lost in urine because of osmotic diuresis. Hypokalemia (low blood potassium concentration) often follows treatment. This increases the risk of dangerous irregularities in the heart rate. Therefore, continuous observation of the heart rate is recommended, as well as repeated measurement of the potassium levels and addition of potassium to the intravenous fluids once levels fall below 5.3 mmol/l. If potassium levels fall below 3.3 mmol/l, insulin administration may need to be interrupted to allow correction of the hypokalemia.
The administration of sodium bicarbonate solution to rapidly improve the acid levels in the blood is controversial. There is little evidence that it improves outcomes beyond standard therapy, and indeed some evidence that while it may improve the acidity of the blood, it may actually worsen acidity inside the body's cells and increase the risk of certain complications. Its use is therefore discouraged, although some guidelines recommend it for extreme acidosis (pH<6.9), and smaller amounts for severe acidosis (pH 6.9–7.0).
Cerebral edema, if associated with coma, often necessitates admission to intensive care, artificial ventilation, and close observation. The administration of fluids is slowed. The ideal treatment of cerebral edema in DKA is not established, but intravenous mannitol and hypertonic saline (3%) are used—as in some other forms of cerebral edema—in an attempt to reduce the swelling.
Resolution of DKA is defined as general improvement in the symptoms, such as the ability to tolerate oral nutrition and fluids, normalization of blood acidity (pH>7.3), and absence of ketones in blood (<1 mmol/l) or urine. Once this has been achieved, insulin may be switched to the usual subcutaneously administrered regimen, one hour after which the intravenous administration can be discontinued.
In people with suspected ketosis-prone type 2 diabetes, determination of antibodies against glutamic acid decarboxylase and islet cells may aid in the decision whether to continue insulin administration long-term (if antibodies are detected), or whether to withdraw insulin and attempt treatment with oral medication as in type 2 diabetes. Generally speaking, routine measurement of C-peptide as a measure of insulin production is not recommended unless there is genuine doubt as to whether someone has type 1 or type 2 diabetes.
Diabetic ketoacidosis occurs in 4.6–8.0 per 1000 people with diabetes annually. Rates among those with type 1 diabetes are higher with about 4% in United Kingdom developing DKA a year while in Malaysia the condition affects about 25% a year. In the United States, 135,000 hospital admissions occur annually as a result of DKA, at an estimated cost of $2.4 billion or a quarter to a half the total cost of caring for people with type 1 diabetes. There has been a documented increasing trend to hospital admissions. The risk is increased in those with an ongoing risk factor, such as an eating disorder, and those who cannot afford insulin. About 30% of children with type 1 diabetes receive their diagnosis after an episode of DKA.
The first full description of diabetic ketoacidosis is attributed to Julius Dreschfeld, a German pathologist working in Manchester, United Kingdom. In his description, which he gave in an 1886 lecture at the Royal College of Physicians in London, he drew on reports by Adolph Kussmaul as well as describing the main ketones, acetoacetate and β-hydroxybutyrate, and their chemical determination. The condition remained almost universally fatal until the discovery of insulin in the 1920s; by the 1930s, mortality had fallen to 29 percent, and by the 1950s it had become less than 10 percent. The entity of cerebral edema due to DKA was described in 1936 by a team of doctors from Philadelphia.
Numerous research studies since the 1950s have focused on the ideal treatment for diabetic ketoacidosis. A significant proportion of these studies have been conducted at the University of Tennessee Health Science Center and Emory University School of Medicine. Treatment options studied have included high- or low-dose intravenous, subcutaneous or intramuscular (e.g. the "Alberti regime") insulin, phosphate supplementation, need for a loading dose of insulin, and appropriateness of using bicarbonate therapy in moderate DKA. Various questions remain unanswered, such as whether bicarbonate administration in severe DKA makes any real difference to the clinical course, and whether an insulin loading dose is needed in adults.
The entity of ketosis-prone type 2 diabetes was first fully described in 1987 after several preceding case reports. It was initially thought to be a form of maturity onset diabetes of the young, and went through several other descriptive names (such as "idiopathic type 1 diabetes", "Flatbush diabetes", "atypical diabetes" and "type 1.5 diabetes") before the current terminology of "ketosis-prone type 2 diabetes" was adopted.
- Misra, S; Oliver, NS (28 October 2015). "Diabetic ketoacidosis in adults" (PDF). BMJ (Clinical research ed.). 351: h5660. doi:10.1136/bmj.h5660. PMID 26510442.
- Bialo, SR; Agrawal, S; Boney, CM; Quintos, JB (15 February 2015). "Rare complications of pediatric diabetic ketoacidosis". World journal of diabetes. 6 (1): 167–74. doi:10.4239/wjd.v6.i1.167. PMC . PMID 25685287.
- Kitabchi AE, Umpierrez GE, Miles JM, Fisher JN (July 2009). "Hyperglycemic crises in adult patients with diabetes". Diabetes Care. 32 (7): 1335–43. doi:10.2337/dc09-9032. PMC . PMID 19564476. Archived from the original on 2016-06-25.
- Ferri, Fred F. (2010). Ferri's Differential Diagnosis: A Practical Guide to the Differential Diagnosis of Symptoms, Signs, and Clinical Disorders. Elsevier Health Sciences. p. 146. ISBN 0323076998. Archived from the original on 2017-09-08.
- Maletkovic, J; Drexler, A (December 2013). "Diabetic ketoacidosis and hyperglycemic hyperosmolar state". Endocrinology and metabolism clinics of North America. 42 (4): 677–95. doi:10.1016/j.ecl.2013.07.001. PMID 24286946.
- Joint British Diabetes Societies Inpatient Care Group (September 2013). "The Management of Diabetic Ketoacidosis in Adults" (pdf). p. 8. Archived (PDF) from the original on 24 March 2016. Retrieved 14 August 2015.
- Eledrisi MS, Alshanti MS, Shah MF, Brolosy B, Jaha N (May 2006). "Overview of the diagnosis and management of diabetic ketoacidosis". American Journal of the Medical Sciences. 331 (5): 243–51. doi:10.1097/00000441-200605000-00002. PMID 16702793.
- Powers AC (2005). Kasper DL, Braunwald E, Fauci AS, et al., eds. "Harrison's Principles of Internal Medicine" (16th ed.). New York, NY: McGraw-Hill: 2152–2180. ISBN 0-07-139140-1.
- Joint British Diabetes Societies Inpatient Care Group (March 2010). "The Management of Diabetic Ketoacidosis in Adults" (PDF). NHS Diabetes. Archived from the original on 2012-05-04. Retrieved 2012-05-01.
- Glaser N (June 2006). "New perspectives on the pathogenesis of cerebral edema complicating diabetic ketoacidosis in children". Pediatric Endocrinology Reviews. 3 (4): 379–86. PMID 16816806.
- Brown TB (March 2004). "Cerebral oedema in childhood diabetic ketoacidosis: Is treatment a factor?". Emergency Medical Journal. 21 (2): 141–4. doi:10.1136/emj.2002.001578. PMC . PMID 14988335. Archived from the original on 2016-04-13.
- Umpierrez GE, Smiley D, Kitabchi AE (March 2006). "Narrative review: ketosis-prone type 2 diabetes mellitus" (PDF). Annals of Internal Medicine. 144 (5): 350–7. doi:10.7326/0003-4819-144-5-200603070-00011. PMID 16520476. Archived (PDF) from the original on 2008-12-05.
- Taylor, Simeon I.; Blau, Jenny E.; Rother, Kristina I. (August 2015). "SGLT2 Inhibitors May Predispose to Ketoacidosis". The Journal of Clinical Endocrinology & Metabolism. 100 (8): 2849–2852. doi:10.1210/jc.2015-1884. PMC . PMID 26086329.
- Kitabchi AE, Umpierrez GE, Murphy MB, Kreisberg RA (December 2006). "Hyperglycemic crises in adult patients with diabetes: a consensus statement from the American Diabetes Association". Diabetes Care. 29 (12): 2739–48. doi:10.2337/dc06-9916. PMID 17130218. Archived from the original on 2010-03-27.
- Dunger DB, Sperling MA, Acerini CL, et al. (February 2004). "European Society for Paediatric Endocrinology/Lawson Wilkins Pediatric Endocrine Society consensus statement on diabetic ketoacidosis in children and adolescents". Pediatrics. 113 (2): e133–40. doi:10.1542/peds.113.2.e133. PMID 14754983. Archived from the original on 2009-09-12.
- Klocker AA, Phelan H, Twigg SM, Craig ME (July 2013). "Blood β-hydroxybutyrate vs. urine acetoacetate testing for the prevention and management of ketoacidosis in Type 1 diabetes: a systematic review". Diabet. Med. 30 (7): 818–24. doi:10.1111/dme.12136. PMID 23330615.
- Misra, S; Oliver, NS (January 2015). "Utility of ketone measurement in the prevention, diagnosis and management of diabetic ketoacidosis". Diabetic Medicine. 32 (1): 14–23. doi:10.1111/dme.12604. PMID 25307274.
- "Type 1 diabetes in adults: diagnosis and management". National Institute for Health and Care Excellence. August 2015. Archived from the original on 9 August 2016. Retrieved 10 February 2016.
- Edge J (May 2009). "BSPED Recommended DKA Guidelines 2009" (PDF). British Society for Paediatric Endocrinology and Diabetes. Archived from the original (PDF) on 2011-10-27. Retrieved 2009-07-12.
- Andrade-Castellanos, CA; Colunga-Lozano, LE; Delgado-Figueroa, N; Gonzalez-Padilla, DA (21 January 2016). "Subcutaneous rapid-acting insulin analogues for diabetic ketoacidosis". The Cochrane database of systematic reviews. 1: CD011281. doi:10.1002/14651858.CD011281.pub2. PMID 26798030.
- Silverstein J, Klingensmith G, Copeland K, et al. (January 2005). "Care of children and adolescents with type 1 diabetes: a statement of the American Diabetes Association". Diabetes Care. 28 (1): 186–212. doi:10.2337/diacare.28.1.186. PMID 15616254. Archived from the original on 2016-04-19.
- Dreschfeld J (1886). "The Bradshawe Lecture on Diabetic Coma". British Medical Journal. 2 (1338): 358–63. doi:10.1136/bmj.2.1338.358. PMC . PMID 20751675.
- Kitabchi AE, Umpierrez GE, Fisher JN, Murphy MB, Stentz FB (May 2008). "Thirty years of personal experience in hyperglycemic crises: diabetic ketoacidosis and hyperglycemic hyperosmolar state". Journal of Clinical Endocrinology and Metabolism. 93 (5): 1541–52. doi:10.1210/jc.2007-2577. PMC . PMID 18270259.
- Dillon ES, Riggs HE, Dyer WW (1936). "Cerebral lesions in uncomplicated fatal diabetic acidosis". American Journal of the Medical Sciences. 3 (3): 360–365. doi:10.1097/00000441-193609000-00007.
- Winter WE, Maclaren NK, Riley WJ, Clarke DW, Kappy MS, Spillar RP (February 1987). "Maturity-onset diabetes of youth in black Americans". New England Journal of Medicine. 316 (6): 285–91. doi:10.1056/NEJM198702053160601. PMID 3543673.