Collecting duct system

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Collecting duct system
Scheme of renal tubule and its vascular supply.
Latintubulus renalis colligens
Anatomical terminology
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Collecting duct system
Scheme of renal tubule and its vascular supply.
Latintubulus renalis colligens
Anatomical terminology

The collecting duct system of the kidney consists of a series of tubules and ducts that connect the nephrons to the ureter. It participates in electrolyte and fluid balance through reabsorption and excretion, processes regulated by the hormones aldosterone and antidiuretic hormone.

There are several components of the collecting duct system, including the connecting tubules, cortical collecting ducts, and medullary collecting ducts.


Simple cuboidal epithelium in the collecting ducts of the pig kidney. The surfaces of the large and small collecting tubes (a and b), the circular structures, are surrounded by the simple cuboidal epithelium.

The segments of the system are as follows:

connecting tubule
initial collecting tubuleBefore convergence of nephrons
cortical collecting ducts
medullary collecting ducts
papillary ducts, also known as duct of Bellini

Connecting tubule[edit]

Main article: Connecting tubule

With respect to the renal corpuscle, the "connecting tubule" is the most proximal part of the collecting duct system. It is adjacent to the distal convoluted tubule, the most distal segment of the renal tubule. Connecting tubules from several adjacent nephrons merge to form cortical collecting tubules, and these may join to form cortical collecting ducts. Connecting tubules of some juxtamedullary nephrons may arch upward, forming an arcade.

The connecting tubule derives from the metanephric blastema, but the rest of the system derives from the ureteric bud. Because of this, some sources group the connecting tubule as part of the nephron, rather than grouping it with the collecting duct system.

Initial collecting tubule[edit]

The initial collecting tubule is a segment with a constitution similar as the collecting duct, but before the convergence with other tubules.

Cortical collecting duct[edit]

The "cortical collecting ducts" receive filtrate from multiple initial collecting tubules and descend into the renal medulla to form medullary collecting ducts.

Medullary collecting duct[edit]

"Medullary collecting ducts" are divided into outer and inner segments, the latter reaching more deeply into the medulla. The variable reabsorption of water and, depending on fluid balances and hormonal influences, the reabsorption or secretion of sodium, potassium, hydrogen and bicarbonate ion continues here. Urea passively transports out of duct here and creates 500mOsm gradient.

Outer segment[edit]

The outer segment of the medullary collecting duct follows the cortical collecting duct. It reaches the level of the renal medulla where the thick ascending limb of loop of Henle borders with the thin ascending limb of loop of Henle[1]:837

Inner segment[edit]

The inner segment is the part of the collecting duct system between the outer segment and the papillary ducts.

Papillary duct[edit]

Main article: Papillary duct

The terminal portions of the medullary collecting ducts are the "papillary ducts", which end at the renal papilla and empty into a minor calyx. It is also called duct of Bellini.

Cell types[edit]

Each component of the collecting duct system contains two cell types, intercalated cells and a segment-specific cell type:

Principal cells[edit]

The principal cell mediates the collecting duct's influence on sodium and potassium balance via sodium channels and potassium channels located on the cell's apical membrane. Aldosterone determines expression of sodium channels with increased aldosterone causing increased expression of luminal sodium channels[2][verification needed]. Aldosterone increases the number of Na⁺/K⁺-ATPase pumps [3]:949 that allow increased sodium reabsorption and potassium secretion.[3]:336 Vasopressin determines the expression of aquaporin channels on the cell surface.[4] Together, aldosterone and vasopressin let the principal cell control the quantity of water that is reabsorbed.

Intercalated cells[edit]

Image depicting intercalated cells

Intercalated cells come in α and β varieties and participate in acid-base homeostasis.

Type of cellSecretesReabsorbs
α-intercalated cellsacid (via an apical H+-ATPase and H+/K+ exchanger) in the form of hydrogen ionsbicarbonate (via band 3, a basolateral Cl-/HCO3- exchanger)[5]
β-intercalated cellsbicarbonate (via pendrin a specialised apical Cl-/HCO3-)acid (via a basal H+-ATPase)

For their contribution to acid-base homeostasis, the intercalated cells play important roles in the kidney's response to acidosis and alkalosis. Damage to the α-intercalated cell's ability to secrete acid can result in distal renal tubular acidosis (RTA type I, classical RTA)(reference).


Diagram outlining movement of ions in nephron, with the collecting ducts on the right.

The collecting duct system is the final component of the kidney to influence the body's electrolyte and fluid balance. In humans, the system accounts for 4–5% of the kidney's reabsorption of sodium and 5% of the kidney's reabsorption of water. At times of extreme dehydration, over 24% of the filtered water may be reabsorbed in the collecting duct system.

The wide variation in water reabsorption levels for the collecting duct system reflects its dependence on hormonal activation. The collecting ducts, in particular, the outer medullary and cortical collecting ducts, are largely impermeable to water without the presence of antidiuretic hormone (ADH, or vasopressin).

The collecting duct system participates in the regulation of other electrolytes, including chloride, potassium, hydrogen ions, and bicarbonate.


  1. ^ Boron, Walter F. (2005). Medical Physiology: A Cellular and Molecular Approach (updated ed.). Philadelphia: Elsevier/Saunders. ISBN 1-4160-2328-3. 
  2. ^ Physiology at MCG 7/7ch03/7ch03p19 – "The Nephron: Collecting Duct"
  3. ^ a b Guyton, Arthur C.; John E. Hall (2006). Textbook of Medical Physiology (11 ed.). Philadelphia: Elsevier Saunders. ISBN 0-7216-0240-1. 
  4. ^ Schlatter, Eberhard; Schafer, James A. (1987). "Electrophysiological studies in principal cells of rat cortical collecting tubules ADH increases the apical membrane Na+-conductance". Pflügers Archiv European Journal of Physiology 409: 81. doi:10.1007/BF00584753. 
  5. ^ Physiology at MCG 7/7ch07/7ch07p17 – "Intercalated Cells"

External links[edit]