Diabetic ketoacidosis

Diabetic Ketoacidosis (DKA)

Diabetic ketoacidosis (DKA) is an acute, life-threatening metabolic emergency characterized by:

Hyperglycemia
Ketosis
High anion gap metabolic acidosis

It results from absolute or relative insulin deficiency combined with increased counter-regulatory hormones:

Glucagon
Catecholamines
Cortisol
Growth hormone

DKA occurs most commonly in:

Type 1 Diabetes Mellitus
but can also occur in:
Type 2 Diabetes Mellitus
especially during severe stress or with SGLT2 inhibitor use.

Diagnostic Criteria

Classical Diagnostic Triad

Parameter	Typical DKA Finding
Blood glucose	>250 mg/dL
Arterial pH	<7.30
Serum bicarbonate	<15 mEq/L
Ketones(ketonemia or ketonuria)	Positive
Anion gap	Elevated

The arterial pH may be normal or even raised if other types of metabolic or respiratory alkalosis coexist, eg, in individuals with vomiting or diuretic use.

In Diabetic Ketoacidosis, metabolic acidosis is always present by definition, because ketone bodies (β-hydroxybutyrate, acetoacetate) accumulate.

But the arterial pH may sometimes appear near normal because of strong respiratory compensation from hyperventilation (Kussmaul breathing).

The primary disorder is:

↓ HCO₃⁻ → metabolic acidosis

Compensation:

Hyperventilation → ↓ PaCO₂ → raises pH toward normal

So you can see situations like:

Parameter	Example
pH	7.36 (near normal)
HCO₃⁻	10 mEq/L
PaCO₂	18 mmHg
Anion gap	High
Ketones	Positive

This is still DKA despite “normal” pH.

Important points:

Low bicarbonate + high anion gap + ketones are more reliable than pH alone.
Venous/arterial pH can be:

low → usual DKA
near normal → compensated DKA
occasionally alkalemic if mixed disorder exists (e.g., vomiting causing metabolic alkalosis)

Winter’s formula helps determine if respiratory compensation is appropriate:

PaCO_2 = (1.5 \times HCO_3^-) + 8 \pm 2

If measured PaCO₂ is:

higher than expected → superimposed respiratory acidosis
lower than expected → additional respiratory alkalosis

So, normal pH does not exclude DKA.

Severity Classification

Severity	Mild	Moderate	Severe
pH	7.25–7.30	7.00–7.24	<7.00
Bicarbonate	15–18	10–14	<10
Mental status	Alert	Drowsy	Stupor/coma
Anion gap	Elevated	Elevated	Elevated

Pathophysiology

Absolute or Relative Insulin Deficiency

Causes:

Reduced glucose utilization
Increased hepatic glucose production
Increased lipolysis
Ketogenesis

Hormonal Changes

Hormone	Effect
Glucagon	Ketogenesis, gluconeogenesis
Catecholamines	Lipolysis
Cortisol	Insulin resistance
Growth hormone	Reduced glucose uptake

Metabolic Pathogenesis

1. Hyperglycemia

Mechanisms:

Increased gluconeogenesis
Glycogenolysis
Reduced peripheral uptake

Result:Severe hyperglycemia/Osmotic diuresis

2. Ketogenesis

Insulin deficiency activates:

Hormone-sensitive lipase

Fat breakdown → free fatty acids → liver.

In liver:

β-oxidation converts FFAs to ketone bodies:

Acetoacetate
β-hydroxybutyrate
Acetone

Result:Metabolic acidosis

3. Osmotic Diuresis

Hyperglycemia exceeds renal threshold.

Consequences:

Polyuria
Sodium loss
Potassium loss
Magnesium/phosphate loss(serum phosphate level in DKA may be elevated despite total-body phosphate depletion.)
Severe dehydration

Typical fluid deficit:5–8 L

Precipitating Factors

Cause	Examples
Infection(Most Common)	Pneumonia, UTI, sepsis
Insulin omission	Noncompliance, pump failure
New-onset diabetes	First presentation
MI/stroke	Acute stress
Drugs	Steroids, thiazides, sympathomimetics
Surgery/trauma	Stress response
Pancreatitis	Severe metabolic stress
Pregnancy	Increased insulin resistance
SGLT2 inhibitors	Euglycemic DKA

Euglycemic DKA

Definition

DKA with:

Glucose <250 mg/dL
Significant ketosis and acidosis

Associated with:

Starvation
Pregnancy
Alcohol use
SGLT2 inhibitors

Common drugs:Empagliflozin/Dapagliflozin/Canagliflozin

Clinical Features

Symptoms

Symptom	Mechanism
Polyuria	Osmotic diuresis
Polydipsia	Dehydration
Weight loss	Catabolism
Vomiting	Acidosis
Abdominal pain	Ketosis/acidosis
Weakness	Electrolyte loss
Altered sensorium	Hyperosmolarity/acidosis
polyphagia

Signs

Sign	Mechanism
Tachycardia	Hypovolemia
Hypotension	Volume depletion
Dry mucosa	Dehydration
Kussmaul breathing	Respiratory compensation
Fruity breath	Acetone
Reduced GCS	Severe acidosis

Kussmaul Respiration

Deep, labored,tachypneic respiration due to severe metabolic acidosis.

Purpose:

Reduce PaCO₂
Compensate acidosis

Laboratory Findings

Investigation	Typical Finding
Blood glucose	Elevated
ABG/VBG	Metabolic acidosis
Serum ketones	Positive
β-hydroxybutyrate(Best ketone marker)	Elevated
Anion gap	Increased
Serum potassium	Normal/high initially
Sodium	Usually low
Creatinine	Elevated
Osmolality	Elevated
ECG	Detect K⁺-related changes
Blood/Urine/sputum Culture
serum lipase,Lipase increases	do not diagnose pancreatitis based only on elevated pancreatic enzymes in DKA.
HBA1C
CBC	Leukocytosis (stress response or Infection )
Chest Xray
Lipids	Lipid derangement is also commonly seen in patients with DKA. Which improves with insulin

In Diabetic Ketoacidosis, the main ketone body is β-hydroxybutyrate (3-HB), not acetoacetate.

Normally:β-hydroxybutyrate : acetoacetate ratio ≈ 1:1

But in severe DKA:

ratio may increase to 10:1
meaning much more β-hydroxybutyrate is produced.

The commonly used nitroprusside ketone test (urine ketone strip):detects only acetoacetate

does NOT detect β-hydroxybutyrate properly.

So in early severe DKA:ketone strip may underestimate severity.

During Treatment

When insulin is given:β-hydroxybutyrate decreases first

it gets converted into acetoacetate

So paradoxically:urine ketone test may become more positive initially,even though the patient is actually improving.

Serum Potassium in DKA

Total body potassium is depleted despite normal/high serum K⁺.

Why?

Acidosis shifts K⁺ extracellularly
Insulin deficiency prevents cellular uptake

Once insulin therapy starts:K⁺ rapidly falls

Hence:Frequent monitoring mandatory

Corrected Sodium in DKA

Hyperglycemia lowers measured sodium.

Formula:Corrected Na+=Measured Na+ +1.6×100(Glucose−100)

(Glucose in mg/dL)

Effective Serum Osmolality=2(Na+)+18Glucose

Anion Gap

Anion Gap=Na+−(Cl−+HCO3− )

Normal:8–12 mEq/L

Differential Diagnosis

Condition	Key Difference
HHS	Minimal ketosis
Starvation ketosis	Mild acidosis
Alcoholic ketoacidosis	Alcohol history
Lactic acidosis	High lactate
Toxic alcohols	Osmolar gap

Management of DKA

ICU Indications

Indication	Reason
Severe DKA	pH <7
Shock	Vasopressor need
Altered sensorium	Airway risk
Severe electrolyte abnormality	Arrhythmia risk
Mechanical ventilation	Critical illness

Fluid Therapy in DKA

Initial Fluid:First Hour

0.9% saline 15–20 mL/kg
Usually 1–1.5 L first hour

Subsequent Fluid Choice

Corrected Na⁺	Fluid
Low	Continue normal saline
Normal/high	Switch to 0.45% saline

Maintenance Fluid rate -250–500 mL/hour

Because the average DKA patient has:

5–8 L total fluid deficit(10% to 15% of the body weight.)

Typical replacement:

About 50% deficit in first 8–12 hours
Remaining over next 12–24 hours

When Glucose Falls to 200 mg/dL

Add dextrose:D5 + 0.45% saline

Goal:Continue insulin safely and Clear ketones

Role of Balanced Crystalloids

Balanced crystalloids (e.g., Ringer’s Lactate) may:

Reduce hyperchloremic acidosis
Improve renal outcomes

Increasingly guideline-supported.

American Diabetes Association

Fluid therapy must be individualized in:

HF
renal failure
elderly

Insulin Therapy

Insulin must continue until:Anion gap closes and Ketosis resolves

NOT merely until glucose normalizes.

IV Regular Insulin

Standard Regimen —Continuous Infusion 0.1 U/kg/hour IV

Some protocols:

Bolus 0.1 U/kg then infusion
Others omit bolus(hourly insulin infusion at 0.14 U/kg/hr.)

Target Glucose Fall

Desired fall:50–75 mg/dL/hour

If not falling adequately: Increase infusion rate

When Glucose <200 mg/dL

Reduce insulin infusion: 0.02–0.05 U/kg/hr

Continue dextrose infusion.

In a patient with euglycemic DKA (glucose level <250 mg/dL), insulin boluses should not be administered to prevent a rapid decline in blood glucose levels. The insulin infusion is given at a lower rate of 0.05 U/kg/hr. These patients should receive dextrose 5% to 10% in the fluids from the beginning.

Potassium Management in DKA

Serum K⁺	Action
>5.2	No K initially
3.3–5.2	Add 20–30 mEq/L K
<3.3	HOLD insulin; replace K first

Bicarbonate Therapy

Not routinely recommended.

Potential harms:

Paradoxical Cerebral acidosis
Hypokalemia
Cerebral edema

When Bicarbonate is Considered

Situation	Reason
pH <7.1	Severe acidemia
Life-threatening hyperkalemia	Temporary stabilization

Phosphate Replacement

Usually Not Routine

Consider if:Severe hypophosphatemia(1.0 mg/dl)

Monitoring in DKA

Parameter	Frequency
Glucose	Hourly
Electrolytes	2–4 hourly
ABG/VBG	2–4 hourly
Anion gap	Serial
Urine output	Hourly
Mental status	Frequent

Resolution Criteria of DKA

Parameter	Target
Glucose	<200 mg/dL(must plus 2 of following)
Bicarbonate	≥15
Venous pH	>7.3
Calculated Anion gap	≤12 mEq/L

Transition to Subcutaneous Insulin

Overlap IV insulin with SC insulin by:1–2 hours

Reason:Prevent rebound ketosis

Stepwise Transition Approach

Step 1 — Confirm Patient Can Eat

If not eating:continue IV insulin with dextrose

Step 2 — Calculate Total Daily Insulin Dose (TDD)

If Patient Already Uses Insulin

Resume home regimen if:previously controlled/reliable adherence

Adjust if needed.

If Newly Diagnosed Diabetes or Unknown Dose

Typical starting dose:

Situation	TDD
Type 1 DM	0.5–0.7 U/kg/day
Type 2 DM	0.3–0.5 U/kg/day

Step 3 — Divide into Basal and Prandial Insulin

Basal-Bolus Regimen

Typical:

50% basal
50% prandial

Example (35 units/day):

Type	Dose
Basal	18 U
Rapid acting before meals	5–6 U TDS

Basal Insulin Options

Glargine,Detemir,NPH Insulin

Prandial Insulin Options

Lispro/Aspart/Regular Insulin

Complications of DKA

Acute Complications

Complication	Mechanism
Hypokalemia	Insulin therapy
Cerebral edema	Rapid osmotic shifts
ARDS	Capillary leak,secondary to pneumonia
AKI	Hypoperfusion,Rhabdomyolysis
Hypoglycemia	Overtreatment
Hyperchloremic acidosis	Excess saline
Thrombosis	Dehydration

Cerebral Edema

Most feared complication in children.

Risk Factors

Rapid osmolar correction,Severe acidosis,Young age
Excess fluids

Features

Headache
Bradycardia
Altered consciousness
Hypertension

Management

Mannitol
Hypertonic saline
ICU care