The history and physical examination are very important in the diagnosis of HHS. In many instances, there is a significant overlap in the signs and symptoms seen in HHS and DKA. In the history taking and the initial assessment, particular attention should be focused on the insulin regiment, missed doses of the oral hypoglycemic agent, overconsumption of carbohydrate-rich diet, or simultaneous use of medications that can trigger hyperglycemia or cause dehydration.

If an infectious process precedes HHS, signs, and symptoms include:

• Fever
• Malaise
• General weakness
• Tachypnea
• Tachycardia

If the precipitating factor is a cardiac, vascular condition, signs and symptoms will include:

• Chest pain
• Chest tightness
• A headache
• Dizziness
• Palpitation

The typical clinical presentation of patients with HHS is increased urination (polyuria) and increase water intake (polydipsia). This is a result of the stimulation of the thirst center in the brain from severe dehydration and increased serum osmolarity. Weakness, malaise, and lethargy can also be part of the complaint.

Severe dehydration from HHS can also affect the skin and integumentary system. Typically, the skin and the oral mucosa are dry with a delayed capillary refill.

The most important distinguishing factor in HHS is the presence of neurological signs. Decreased cerebral blood flow from severe dehydration can cause:

• Focal neurological deficit
• Disturbance in visual acuity
• Delirium
• Coma

A system based approach is necessary for the physical assessment:

• General appearance: Patient with HHS are generally ill-appearing with altered mental status
• Cardiovascular: Tachycardia, orthostatic hypotension, weak and thready pulses
• Respiratory Rate: Can be normal, tachypnea might be present if acidosis is profound
• Skin: Delayed capillary refill, poor skin turgor, skin tenting might not be present even in severe dehydration because of obesity
• Genitourinary: Decreased urine output
• Central Nervous System (CNS): Focal neurological deficit, lethargy with low Glasgow Coma Score. In severe cases of HHS, patients might be comatose.

The physical examination should also focus on other comorbidities associated with diabetes mellitus. Acanthosis nigricans, oral thrush, vulvovaginitis, multiple pustular skin lesions might all indicate poor glycemic control. This is important if HHS is the initial presentation of type 2 diabetes.

The diagnostic criteria for HHS were developed as a result of cases series reported by Gerich et al. Arieff and Carroll also contributed to this work in a separate study both of which were published in 1971.[27]

According to the recommendation of the American Diabetic Association and current international guideline, HHS is defined by plasma glucose level greater than 600 mg/dL, plasma effective osmolarity greater than 320 mOsm/L, and absence of significant ketoacidosis.[28]

Hyperosmolar hyperglycemic non-ketotic coma is no longer accepted as a diagnostic nomenclature because not all patients with HHS will present with coma even in the presence of significant hyperglycemia and hyperosmolarity.

The evaluation of HHS requires a detailed history and physical examination. The onset of symptoms and the precipitating factors are very important to elicit from patients. That apart, ancillary studies are also necessary as part of the diagnostic workup.

The first test in HHS is a fingerstick to determine the serum glucose level. The value is usually between 600 to 1200 mg/dl. The higher the level of glucose, the greater the serum osmolarity and the higher the degree of dehydration.

Glucose

The glucose level should be monitored hourly to guard against a sudden and precipitous drop, during treatment with isotonic fluid and insulin. This is to prevent the development of cerebral edema which is the most dreaded complication in both DKA and HHS. The risk of cerebral edema is higher in HHS.

Hemoglobin A1C

This is a measure of long-term glycemic control and is a useful tool in the assessment of new-onset diabetes mellitus.

Serum Osmolarity

The serum osmolality is very high in HHS. Levels between 320 to 400mOsm/kg is very common in HHS. Normal serum osmolarity is around 280 -290 mOsm/kg. In patients with higher serum osmolarity are associated with alteration in the level of consciousness and might eventually lead to a coma.

The comprehensive metabolic panel allows for the determination of electrolyte derangements seen in HHS.

Sodium

The sodium level is falsely low (pseudohyponatremia). The hyperglycemic state creates an osmotic gradient drawing water from the intracellular space into the extracellular space. The correct or true sodium level is usually calculated using the formula:

Corrected Sodium = Measured sodium + (((Serum glucose - 100)/100) x 1.6)

Potassium

The level of potassium might be high or low. A low level of insulin can cause an extracellular shift of potassium. However, because of ongoing urinary losses, the total body potassium is low in both HHS and DKA. Care must be taken to avoid aggressive correction of hypokalemia in HHS because of decreased glomerular filtration rate from dehydration

Bicarbonate

Bicarbonate level is usually close to normal in HHS, around 8 to 12 mmol/L because the production of ketone bodies is minimal as compared to DKA where bicarbonate level is usually very low. The anion gap in HHS is close to normal. On the contrary, the anion gap is usually above 12 mmol/L in DKA. The anion gap is determined by the formula:

(Na +K) -(Cl +HC0)

If the anion gap is high in HHS, it is usually because of the production of lactic acid from tissue hypoperfusion and decreased circulation.

Magnesium

The magnesium level might be low in HHS.

Phosphorus

Hyperphosphatemia is common in HHS especially if rhabdomyolysis is a complication. This is as a result of muscular tissue breakdown. Administration of insulin and hydration with fluid might lower the phosphorus level as it is driven back into cells. Some of the phosphorus also get excreted by the kidneys as end-organ perfusion improves.

Ketones

Ketonemia is very minimal in HHS. Electrolytes should be monitored serially every 2 to 3 hours in the management of HHS.

Arterial Blood Gases

The role of blood gas is to determine the level of acidosis. In HHS, pH is usually above or around 7.30 The pC0 might be low from hyperventilation. In DKA, serum pH is usually much lower ranging from 6.8 to around 7.2 on initial presentation. Acidosis in HHS is mainly as a result of dehydration and compromised end-organ perfusion.

Arterial blood gases should be monitored every 2 to 3 hours in HHS.

Renal Function

The BUN and creatine levels are usually elevated reflecting prerenal azotemia. As hydration and insulin therapy is initiated, these values will usually drop and eventually normalized.

Serum Enzymes

The level of serum enzymes like creatinine kinase, aldolase, transaminases is usually high from hemoconcentration and dehydration.

Complete Blood Count

The white blood cell count might be high because of the stress response or as a result of an infectious process triggering HHS. In most cases, hemoglobin and hematocrit levels are elevated. If the white count is elevated, blood, urine culture, and a chest X-ray might be needed to find the source of infection.

Urine Analysis

Urine specific gravity is high in HHS. Glycosuria and ketonuria are also present.

Treatment of HHS requires a multidisciplinary approach. Consultation with an endocrinologist and intensive care specialist is recommended. Appropriate resuscitation with attention to the principle of Airway, Breathing, Circulation (ABC) should be initiated. Patients with HHS can present with altered mental status as a result of significant fluid depletion and decreased cerebral perfusion. A good rule of thumb is to secure the airway if the Glasgow coma score is less than 8.

Aggressive hydration with isotonic fluid with electrolyte replacement is the standard practice in the management of HHS. An initial fluid bolus of 15 to 20 ml/kg followed by an infusion rate of 200 to 250ml/hour is the recommended rate for adults. In pediatric patients, the infusion should run at about twice the maintenance rate. Hydration with isotonic fluid has been shown to help in reducing the amount of counterregulatory hormones produced during HHS. The use of this alone can reduce serum glucose by about 75 to 100 mg/hour. The serum potassium in HHS is usually high, but the total body potassium is low as a result of the extracellular shift from lack of insulin. Potassium replacement should be started when the serum potassium is between 4 to 4.5 mmol/L.[29]

Care should be taken to avoid starting insulin drip in the initial stage of treatment as this might cause a rapid drop in serum glucose leading to cerebral edema. It is recommended to try to keep the glucose level around 300 mg/dL to prevent the development of cerebral edema.

In pediatrics, rehydration and electrolyte correction over a longer period, 48 hours may help in the prevention of cerebral edema.[29][30]

The differential diagnosis in HHS is divided into 2 broad groups: clinical conditions causing altered mental status and clinical conditions causing hyperglycemia.

The following are some examples of condition that can cause an alteration in mental status:

• Hypoglycemia
• Hyponatremia
• Hypernatremia
• Hyperammonemia
• Severe intoxication with drugs or alcohol
• Uremic encephalopathy

Hyperglycemia can develop with diabetic ketoacidosis and diabetic insipidus.

A detailed history, thorough physical examination and use of ancillary studies can help to establish a diagnosis quickly.[23]

HHS is a potentially fatal medical condition. Knowledge of pathophysiology and clinical presentation is necessary for the best management outcome.

In general, the overall mortality is low and is usually due to the underlying illness that caused the hyperglycemic crisis. Elderly patients who present with severe coma and hypotension have a poor prognosis compared to younger cohorts.

Electrolyte abnormalities as a consequence of the treatment of HHS are quite frequent. Care needs to be taken to ensure frequent monitoring and avoid adverse side effects. Common electrolyte disturbances include hypokalemia and hypoglycemia. 

Cerebral edema is a feared but rare complication in HHS. This is more common in the pediatric population and occurs due to the rapid lowering of glucose levels.

Diabetic education including instructions on adequate hydration is essential to avoid recurrent episodes. 

Hyperosmolar Hyperglycemic Nonketotic Coma is a serious complication of Type II Diabetes. Most patients will end up being admitted to the intensive care unit. To improve patient outcome, an interprofessional approach with good care communication and coordination between the Intensivist, nurse, dietician, and the endocrinologist is necessary.