Renal tubular acidosis: Pathology review

Last updated: June 20, 2025

Renal tubular acidosis: Pathology review

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Hyponatremia: Clinical
Syndrome of inappropriate antidiuretic hormone secretion (SIADH)
Hyperkalemia: Clinical
Hyperkalemia
Hypokalemia
Hypokalemia: Clinical
Chronic kidney disease: Clinical
Chronic kidney disease
Renal failure: Pathology review
Nephritic syndromes: Pathology review
Nephrotic syndromes: Pathology review
Acute kidney injury: Clinical
Nephritic and nephrotic syndromes: Clinical
Phosphate, calcium and magnesium homeostasis
ACE inhibitors, ARBs and direct renin inhibitors
Potassium sparing diuretics
Loop diuretics
Thiazide and thiazide-like diuretics
Osmotic diuretics
Heart failure: Clinical
Hyperaldosteronism
Diabetes insipidus and SIADH: Pathology review
Hyponatremia
Non-steroidal anti-inflammatory drugs
Asthma: Clinical
Alport syndrome
Metabolic and respiratory alkalosis: Clinical
The role of the kidney in acid-base balance
Minimal change disease
Focal segmental glomerulosclerosis (NORD)
Membranous nephropathy
Membranoproliferative glomerulonephritis
Amyloidosis
Lupus nephritis
Rapidly progressive glomerulonephritis
IgA nephropathy (NORD)
Poststreptococcal glomerulonephritis
Acid-base disturbances: Pathology review
Renal tubular acidosis: Pathology review
Acid-base map and compensatory mechanisms
Aortic valve disease
Mitral valve disease
Dilated cardiomyopathy
Valvular heart disease: Clinical
Cardiomyopathies: Pathology review
Restrictive cardiomyopathy
Hypertrophic cardiomyopathy
Atherosclerosis and arteriosclerosis: Pathology review
Heart failure: Pathology review
Calcium channel blockers
Lipid-lowering medications: Statins
Myocardial infarction
ECG cardiac infarction and ischemia
Coronary artery disease: Clinical
Coronary artery disease: Pathology review
Coronary steal syndrome
Atrial fibrillation
Atrioventricular nodal reentrant tachycardia (AVNRT)
Heart blocks: Pathology review
ECG cardiac hypertrophy and enlargement
Valvular heart disease: Pathology review
Supraventricular arrhythmias: Pathology review
Hypertension: Pathology review
Vasculitis: Pathology review

Questions

USMLE® Step 1 style questions USMLE

0 of 3 complete

Start
A 76-year-old woman presents to the emergency department with fatigue, decreased appetite, and muscle weakness. Past medical history includes chronic migraines, hypertension, gastroesophageal reflux, and a recent episode of podagra. Current medications include topiramate, lisinopril, acetazolamide, omeprazole, and probenecid. Temperature is 37.0°C (98.6°F), pulse is 104/min, respirations are 24/min, and blood pressure is 96/66 mmHg. Arterial blood gas and laboratory testing are obtained, and the results are shown below.  
 
 Laboratory value  Result  Reference range 
 Arterial blood gas  
 pH  7.1  7.35-7.45 
 pCO2 26 mmHg  33-45 mmHg 
 pO2  84 mmHg  75-105 mmHg 
 Blood, serum, plasma  
 Sodium  134 mEq/L  136-146 mEq/L 
 Chlorine  110 mEq/L  95-105 mEq/L 
 Potassium   6.1 mEq/L  3.5-5 mEq/L 
 Bicarbonate  14 mEq/L  22-28 mEq/L 
 Urine   
 pH  5.0  4.6-8 
   
Which of the following medications most likely contributed to this patient’s disease? 

Transcript

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In the Emergency Department, two people came in with rapid, shallow breathing and tachycardia. The first one is 45 year old Olga who also has systemic lupus erythematosus and the second one is 39 year old Fred. An arterial blood gas was taken, along with electrolytes. Results showed that Olga had low pH, low bicarbonate and pCO2 levels and her potassium level was also low. Fred also had low pH, low bicarbonate and pCO2 levels, but his potassium level was high. Based on the ABG results, the diagnosis of normal anion gap metabolic acidosis was made. In order to identify the cause of their normal gap metabolic acidosis, more investigations were done and the urine anion gap showed that both individuals had a low urinary anion gap, which suggests that the cause was renal.

Okay, now, a normal anion gap metabolic acidosis can have renal causes. Like when a lot of bicarbonate is lost through the urinary tract- which happens in type II renal tubular acidosis. A normal anion gap metabolic acidosis can also happen when too many hydrogen ions are retained, like in type I and type IV renal tubular acidosis. Now, there’s also a type III renal tubular acidosis, where both the proximal and distal tubules are affected. This is a pretty rare situation and the causes are not well understood, so it’s unlikely to be tested.

Okay, now, let’s review the physiology of the tubules. The proximal tubule is affected in RTA type II. It’s lined by brush border cells which have two surfaces: One is the apical surface that faces the tubular lumen and is lined with microvilli, and the other is the basolateral surface, which faces the peritubular capillaries. Now, a lot of bicarbonate is reabsorbed here. When bicarbonate approaches the apical surface it binds to hydrogen to form carbonic acid, which will be split into water and carbon dioxide by carbonic anhydrase. The water and carbon dioxide diffuse into the cells where carbonic anhydrase facilitates the reverse reaction and combines them to form carbonic acid, which dissociates into bicarbonate and hydrogen. Then bicarbonate will get into the blood with the help of a sodium bicarbonate cotransporter on the basolateral surface. Now, the proximal tubule is also responsible for reabsorbing glucose, as well as amino acids, sodium, chloride, potassium, phosphate, water and uric acid.

Okay, so now let’s look at the distal tubule and collecting duct which are affected in type I and type IV RTA. First, they are lined with alpha-intercalated cells which also move bicarbonate and hydrogen from the tubule into the cell with the help of carbonic anhydrase. The alpha intercalated cells also secrete hydrogen across the apical surface and into the tubule with the help of a hydrogen ATPase and a potassium hydrogen ATPase. Once in the lumen, hydrogen binds to phosphate or ammonia to form relatively weak acids like dihydrogen phosphate or ammonium, which then get peed out in the urine. This allows protons to get removed without making the urine too acidic and damaging the cells lining the tubules and the rest of the urinary tract.

The other group of cells in these regions are the principal cells.These cells have a potassium channel that allows potassium into the lumen, and an epithelial sodium channel that allows sodium into the cell. The flow of positively charged sodium ions into cell helps drive the positively charged potassium ions out of the cell against their concentration gradient. There’s also a Na/K ATPase pump on the basolateral surface that again moves 2 potassium ions in for every 3 sodium ions out. All three of these channels are stimulated by aldosterone, and the combined effect is resorption of sodium and loss of potassium.

Key Takeaways

Renal tubular acidosis is a medical condition in which the kidney is unable to secrete acids or reabsorb bicarbonate from the body. When blood is filtered by the kidney, the filtrate passes through the tubules of the nephron, allowing for the exchange of salts, acid equivalents, and other solutes before it drains into the bladder as urine. The metabolic acidosis that results from renal tubular acidosis may be caused either by failure to recover sufficient bicarbonate ions from the filtrate in the proximal tubule or by insufficient secretion of hydrogen ions into the distal tubule. If left untreated, acidemia can cause peripheral vasodilation and shock. Treatment may include alkali supplements like potassium citrate or sodium bicarbonate to neutralize the acid in the blood.

Sources

  1. "Robbins Basic Pathology" Elsevier (2017)
  2. "Harrison's Principles of Internal Medicine, Twentieth Edition (Vol.1 & Vol.2)" McGraw-Hill Education / Medical (2018)
  3. "First Aid for the USMLE Step 1 2018, 28th Edition" McGraw-Hill Education / Medical (2017)
  4. "Nephrolithiasis in Renal Tubular Acidosis" Journal of Urology (1989)
  5. "Pathophysiology of Renal Tubular Acidosis: Core Curriculum 2016" American Journal of Kidney Diseases (2016)
  6. "Nephrolithiasis related to inborn metabolic diseases" Pediatric Nephrology (2009)
  7. "Renal Tubular Acidosis" Pediatric Clinics of North America (2019)
  8. "On the mechanism of renal potassium wasting in renal tubular acidosis associated with the Fanconi syndrome (type 2 RTA)" Journal of Clinical Investigation (1971)