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Colic flexures

The colic flexures, also known as the hepatic and splenic flexures, are the two principal bends in the human colon that facilitate its directional changes within the as part of the . The right colic flexure (hepatic flexure) marks the junction between the and the , positioned adjacent to the inferior surface of the liver's right lobe. The left colic flexure (splenic flexure) denotes the junction between the and the , located near the and typically forming a sharper angle than its right counterpart. These structures are essential for the colon's anatomical configuration, aiding in the propulsion and storage of fecal matter.

Anatomy

Right colic flexure (hepatic flexure)

The right , also known as the hepatic , is the sharp bend in the where the transitions into the , located in the right upper quadrant of the . This marks the transition from the retroperitoneal to the intraperitoneal , facilitating the directional change of the colonic pathway across the . Positioned immediately inferior to the right lobe of the liver, the hepatic flexure derives its name from this close anatomical relationship, which influences its peritoneal positioning and support. It is suspended from the liver by the , a peritoneal fold that contributes to its mobility during abdominal movements. In contrast to the left flexure (splenic flexure), which is relatively fixed by the phrenicocolic anchoring it to the , the right colic flexure exhibits greater mobility due to its less restrictive peritoneal attachments. Anatomically, the right colic flexure is acute (≤90°) in over 97% of cases, as evident in radiographic and cadaveric studies. The flexure maintains specific relations to adjacent structures that define its position within the . Superiorly, it relates to the right lobe of the liver; posteriorly, to the right kidney; and medially, to the descending part of the . These relationships underscore its role in the spatial organization of the right upper abdominal viscera.

Left colic flexure (splenic flexure)

The left colic flexure, also known as the splenic flexure, is the sharp bend in the located in the left upper quadrant of the abdomen, marking the junction between the distal and the proximal . This anatomical feature facilitates the transition of the colon from its horizontal to vertical course, contributing to the overall continuity of the colonic pathway. Positioned in the left hypochondrium at approximately the level of the 11th thoracic vertebra, the left colic flexure lies in close proximity to the , from which it derives its alternative name, and is suspended from the left hemidiaphragm by the phrenicocolic ligament. This ligamentous attachment, along with peritoneal reflections, provides firm fixation, rendering the splenic flexure relatively immobile compared to other colonic segments. The structure's peritoneal coverings include the transverse mesocolon proximally and the descending mesocolon distally, enhancing its stability within the . In terms of dimensions, the left colic flexure typically forms a more acute angle than the right colic flexure, often measuring between 40° and 90°, though variations up to 120° have been observed in anatomical studies. Surrounding structures include the spleen superiorly, where the colic impression on the spleen's visceral surface accommodates the flexure; the tail of the pancreas medially, in direct relation to the flexure's inferior aspect; and the left kidney posteriorly, with the flexure positioned anteriorly to it. These relations underscore the splenic flexure's embedded position in the left upper abdominal compartment.

Embryology and development

Origin from midgut and hindgut

The colic flexures originate from distinct segments of the embryonic gut, reflecting the division of the primitive gut tube into , , and during early . The primitive gut tube forms from the endodermal lining of the around weeks 3 to 4 of embryonic development, as lateral and craniocaudal folding incorporates the yolk sac into the embryo, establishing the foundational structure for gastrointestinal derivatives. This tube differentiates into three regions based on arterial supply and positional cues: the , supplied by the , and the , supplied by the , with the transition occurring at the junction of the proximal two-thirds and distal one-third of the future . The right colic flexure (hepatic flexure) derives from the , specifically the terminal portion connecting the to the proximal two-thirds of the . This segment elongates rapidly between weeks 5 and 10, forming the precursors to the , , , and right , which will eventually position the right flexure near the liver in the adult configuration. In contrast, the left colic flexure (splenic flexure) arises from the , encompassing the distal one-third of the leading into the . The develops concurrently from week 4 onward, contributing to the left , , , and upper , with the flexure's precursor marking the embryological boundary where transitions to vasculature and innervation. These origins from the and establish the flexures' fundamental epithelial and mesenchymal components during weeks 5 to 10, when the gut tube's endodermal layer proliferates and differentiates under the influence of regional signaling molecules, setting the stage for later positional adjustments without altering the segmental derivations. The primitive gut tube's role is pivotal, as its initial partitioning into and domains dictates the flexures' future contributions to colonic continuity and function.

Formation during intestinal rotation

The development of the colic flexures occurs as part of the intricate process of intestinal rotation during fetal embryogenesis, primarily involving the 's herniation, elongation, and repositioning within the . Around weeks 6 to 10 of , the rapidly growing herniates through the umbilical ring into the extraembryonic , forming a primary intestinal loop with the (SMA) as its axis; this loop includes the precursors of the distal , , , , , and proximal two-thirds of the . As the expands, the returns to the between weeks 10 and 12, with the ileocecal region retracting last, allowing the loop to uncoil and assume its definitive configuration. A critical aspect of this repositioning is the counterclockwise rotation of the loop around the axis, totaling 270 degrees and occurring in two phases: an initial 90-degree rotation during herniation (around week 6-7) that positions the cranial limb (future and ) ventrally and the caudal limb (future and ) dorsally, followed by an additional 180-degree rotation upon return (completing by week 10-11). This rotation sweeps the and to the right side of the , establishing the right colic (hepatic) flexure at the junction where the turns superiorly to form the right aspect of the . Concurrently, the left colic (splenic) flexure develops through the differential growth and fixation of the hindgut-derived , influenced by the rotation's leftward sweep of the . Between weeks 10 and 12, the dorsal of the fuses with the posterior , anchoring the left flexure in its position near the and , while the remains suspended by the mesocolon. This fusion process stabilizes the flexures, preventing excessive mobility and ensuring the colon's frame-like arrangement around the . Incomplete or arrested rotation during this period can result in malrotation, where the colic flexures fail to achieve their normal positions, potentially leading to abnormal colonic looping or inadequate mesenteric fixation. Such anomalies arise from disruptions in the 270-degree counterclockwise rotation around the , affecting up to 1 in 500 live births, though many remain asymptomatic until later.

Blood supply and innervation

Arterial supply

The right colic flexure, also known as the hepatic flexure, receives its primary arterial supply from the right colic artery, a branch of the (). This artery arises either directly from the or from a common trunk with the , coursing superiorly to anastomose with branches of the , thereby ensuring robust perfusion to the flexure and adjacent . The , another derivative, contributes significantly by extending its left branch to the right colic flexure, forming an arcade that enhances vascular redundancy in this region. In contrast, the left colic flexure, or splenic flexure, exhibits a dual arterial supply derived from both the superior and inferior mesenteric arteries, reflecting its embryological transition between and territories. The left colic artery, originating from the (IMA), provides the primary inflow via its ascending branch, which directly perfuses the and flexure. This is supplemented by the left branch of the from the , creating a critical junction at the flexure for cross-territorial blood flow. The marginal artery of Drummond plays a pivotal role in interconnecting these supplies, forming a continuous arterial arcade along the colonic that links the and IMA branches, thereby facilitating circulation essential for maintaining perfusion during potential vascular compromise. This anastomotic network is particularly vital at the colic flexures, where it bridges the right and left colic arteries, ensuring hemodynamic stability across the . Anatomical variations in the arterial supply to the colic flexures are common and clinically relevant. The right colic artery is absent in approximately 9% of individuals, with compensation often provided by branches from the middle colic or ileocolic arteries. For the left colic flexure, variations may include incomplete development of the marginal artery, though an accessory left colic artery from the can arise to bolster supply in such cases. These variants underscore the importance of preoperative imaging in surgical planning to avoid iatrogenic ischemia.

Venous and lymphatic drainage

The venous drainage of the right colic flexure (hepatic flexure) parallels its arterial supply, with blood collected primarily by the right colic vein, a tributary of the , which ascends to join the behind the . This pathway ensures efficient return of nutrient-rich blood from the midgut-derived portions of the colon to the liver. In comparison, the left colic flexure (splenic flexure) drains through the left colic vein into the , which courses upward to unite with the before forming the , reflecting its origin. The splenic flexure vein often accompanies this route, directing flow predominantly toward the in most cases. Lymphatic drainage from the right flexure begins in epicolic and paracolic nodes along the colonic wall and margin, progressing through intermediate nodes associated with the right and middle vessels to the near the root of the . These nodes then relay lymph to and the . For the left flexure, lymphatics follow a similar initial pattern but drain via intermediate left nodes to the inferior mesenteric lymph nodes, ultimately reaching para-aortic nodes along the . This directed flow supports immune surveillance and in the respective colonic segments. In , lymphatic patterns at the colic flexures align with these normal drainage pathways, with right flexure tumors typically involving superior mesenteric nodes and left flexure tumors spreading to inferior mesenteric and para-aortic nodes, influencing surgical extent and prognostic staging. Such patterns underscore the importance of region-specific nodal assessment in .

Nerve supply

The colic flexures receive autonomic innervation that differs based on their embryological origins from the and , influencing their regulatory functions. The right colic flexure (hepatic flexure), derived from the , is supplied by sympathetic fibers originating from the greater and lesser thoracic (T5-T12), which in the and superior mesenteric plexuses before distributing to the flexure via periarterial plexuses along the . In contrast, the left colic flexure (splenic flexure), part of the , receives sympathetic innervation from lumbar (L1-L2), synapsing in the inferior mesenteric and traveling along branches of the left colic . Parasympathetic innervation provides excitatory input to the colic flexures, with the right flexure receiving fibers from the (cranial nerve X) via the and superior mesenteric plexuses, extending to the proximal two-thirds of the . The left flexure is innervated by (S2-S4), which join the and follow the vascular supply to the distal colon. These parasympathetic fibers in intramural ganglia of the , facilitating coordinated responses. Sensory innervation of the colic flexures is mediated by visceral afferent fibers that detect distension, , and . For the right flexure, these afferents travel centrally via the to the nucleus tractus solitarius, conveying non-painful sensations of distension. In the left flexure, visceral afferents accompany sympathetic pathways to thoracolumbar (T10-L1) and sacral (S2-S4) dorsal root ganglia, transmitting nociceptive signals from high-threshold mechanoreceptors responsive to excessive distension (>40 mm ) or , which can contribute to patterns in the or back. The innervation of the colic flexures plays a key role in arcs for , where sensory afferents detect rectal distension and trigger parasympathetic-mediated colonic contractions via the recto-colic , propagating contents proximally through the flexures to empty the colon. Sympathetic fibers modulate this process by providing inhibitory tone, ensuring coordinated propulsion without excessive activity.

Physiological role

In colonic motility and transit

The colic flexures are integral to colonic motility, serving as sites where haustral contractions and movements contribute to the mixing and controlled of luminal contents. Haustral contractions, generated by the circular layer in coordination with the taeniae coli, create segmental sacculations (haustra) throughout the colon, including at the flexures; these contractions occur approximately every 30 minutes, promoting to-and-fro mixing that maximizes mucosal contact for gradual processing of without rapid transit. At the right colic flexure (hepatic flexure), motility facilitates the integration and mixing of contents entering from the ileocecal valve into the ascending and transverse colon segments. Propagating pressure sequences originating in the cecum-ascending colon region are highly propulsive (86% of sequences), efficiently advancing material to the hepatic flexure, where the transition to the transverse colon shifts toward less efficient propulsion (only 30% of sequences at or distal to the flexure are propulsive), enabling enhanced mixing via retrograde giant contractions in the proximal colon. This dynamic supports the initial fermentation and water extraction in the transverse colon, with high-amplitude propagating contractions (>90 mmHg) frequently observed proximal to the flexure to drive this mixing process. In contrast, the left colic flexure (splenic flexure) functions as a functional due to its acute and high density of propagating pressure waves in the mid-colon, which slow the advancement of contents into the . This configuration prolongs residence time, allowing for sustained haustral mixing and water absorption; colonic studies demonstrate that delayed progression beyond the splenic flexure by 48–72 hours reflects overall slow , underscoring its role in regulating distal rates at approximately 1 cm/h during mass movements. The angles of the colic flexures further modulate fecal , with the sharper bend at the splenic flexure impeding forward more than the hepatic flexure, potentially exacerbating delays in upright posture; alterations in position, such as ptosis or elevation of the splenic flexure, have been associated with reduced efficiency and chronic transit slowing.

Contribution to absorption and storage

The colic flexures serve as key anatomical expansion points within the colon, contributing to its overall for holding fecal material and facilitating prolonged exposure to absorptive surfaces. The human colon can accommodate approximately 500–600 mL of content in healthy individuals, with the flexures enabling distension and mixing that support this reservoir function. At the right colic flexure (hepatic flexure), which marks the junction between the ascending and , the structure aids in the initial dehydration of delivered from the . This region, part of the ascending colon's absorptive activity, reabsorbs a significant portion of water and electrolytes from the liquid , converting it into a more semisolid form as it progresses. The left colic flexure (splenic flexure), located at the transition from the transverse to the , plays a role in the final phase of water and prior to the . Here, the further compacts the contents by reclaiming remaining fluids, ensuring efficient fecal formation. Additionally, due to its elevated position relative to other colonic segments, the left flexure exhibits potential for gas accumulation, as intestinal gases rise and collect at this higher point under gravitational influence.

Clinical significance

Ischemia and watershed areas

The colic flexures represent sites of potential vascular vulnerability in the colon due to their positions at the junctions of major arterial territories. The hepatic flexure, primarily supplied by branches of the (), is less prone to non-occlusive ischemia owing to its dominant single-vessel perfusion, though it carries risk during occlusion from embolism or , which can lead to extensive right colonic involvement. In contrast, the splenic flexure lies at Griffith's point, a area marking the between the 's left colic branch and the () via the marginal artery of Drummond, rendering it susceptible to ischemia in low-flow states due to variable or tenuous collateral circulation, which is absent in up to 5% of individuals. Ischemic events at these flexures often manifest as ischemic colitis, with symptoms including sudden crampy , tenderness over the affected area, and or bloody diarrhea, typically appearing within 24 hours of onset. Risk factors encompass , , , hypercoagulable states, and medications such as nonsteroidal drugs, which compromise colonic . The condition shows higher incidence in elderly patients, with average onset around age 70 and prevalence rising sharply after 60, as well as in post-surgical cases, particularly following repair where IMA ligation exacerbates hypoperfusion. Approximately 75% of ischemic colitis cases involve the left colon, with nearly 25% affecting the splenic flexure, underscoring the latter's prominence as a high-risk site.

Associated syndromes and pathologies

Splenic flexure syndrome is characterized by the trapping of gas in the splenic flexure, leading to left upper quadrant that may mimic more serious conditions such as cardiac or splenic disorders. This condition arises from localized distension due to air accumulation at the angulated bend of the colon, often exacerbated by dietary factors that promote and gas production, such as high-carbohydrate or high-fiber intake. It is frequently associated with (IBS), where altered colonic motility contributes to gas retention and visceral hypersensitivity, resulting in recurrent episodes of and cramping. Volvulus at the colic flexures represents a mechanical obstruction due to twisting of the colon around its mesentery, with the risk heightened by anatomical variations in colonic mobility. The splenic flexure is particularly susceptible when congenital absence or laxity of fixing ligaments, such as the phrenicocolic or splenocolic ligaments, allows excessive mobility, accounting for less than 1% of all colonic volvuli. Similarly, the hepatic flexure may undergo volvulus in cases of redundant transverse colon, though this is even rarer; transverse colon volvulus overall accounts for 1-4% of all colonic volvuli and may involve the hepatic flexure. These events lead to acute obstruction and potential ischemia if untreated, underscoring the flexures' vulnerability compared to more fixed colonic segments. Adenocarcinomas arising at the colic s are uncommon, representing 2-8% of all colorectal cancers, with a higher incidence at the left-sided splenic flexure due to the general predominance of tumors in the distal colon. These malignancies often present late with obstructive symptoms owing to the flexures' narrow and proximity to surrounding structures, and they exhibit molecular profiles similar to other left-sided colorectal cancers, including in a subset of cases. In contrast, hepatic flexure tumors, while rarer, share right-sided characteristics like poorer but occur less frequently than their splenic counterparts. Inflammatory conditions frequently involve the colic flexures, particularly in and (IBD). In Western populations, diverticula in the or splenic flexure account for about 11% of cases among white patients, where outpouchings become inflamed, leading to localized or formation that may extend to adjacent organs like the . Hepatic flexure diverticulitis is rarer but can mimic biliary pathology due to its proximity to the , often managed conservatively with antibiotics unless complicated. In IBD, commonly affects the flexures during flares, with left-sided disease extending to the splenic flexure in up to one-third of cases, causing continuous mucosal inflammation, bleeding, and urgency. , by contrast, may involve the hepatic or splenic flexures through skip lesions or transmural inflammation, resulting in strictures or fistulas that exacerbate pain and obstructive symptoms during active disease.

Surgical considerations

Surgical mobilization of the colic is a critical component of colorectal procedures, particularly colectomies, where precise techniques are employed to ensure adequate resection margins and anastomotic integrity while minimizing risks to adjacent structures. The hepatic flexure, located at the junction of the ascending and transverse , is generally easier to mobilize due to the inherent mobility of the right colon, which allows for straightforward incision of the along the white line of Toldt and medial reflection without extensive ligamentous divisions. In contrast, the splenic flexure demands more meticulous , often requiring division of the phrenicocolic and splenocolic attachments to achieve complete , as these structures anchor the left colon to the and , increasing technical complexity. In left-sided colectomies, such as or resections, takedown of the splenic flexure is routinely performed to facilitate tension-free and ensure oncologic margins, particularly in cases extending to the . This step involves entering the and dividing the gastrocolic ligament, allowing the flexure to be reflected inferiorly for optimal proximal . For right-sided or extended right colectomies, hepatic flexure similarly extends the resection field but is less encumbered by fixed attachments, enabling easier access to the and head of the if needed. Preservation of the marginal of Drummond during these maneuvers is essential to maintain collateral blood flow to the , as referenced in the vascular supply section. Common complications associated with flexure mobilization include bleeding from the marginal artery, which can occur during ligation of colic vessels and may require meticulous to avoid ischemia. is a notable during splenic flexure procedures, with an incidence of up to 1-2% in laparoscopic approaches, often managed conservatively if minor but potentially necessitating in severe cases. Pancreatic injury, though rare (approximately 0.6%), arises from the proximity of the pancreatic tail to the flexure and can lead to significant morbidity, including fistula formation, emphasizing the need for careful medial dissection. Laparoscopic approaches to flexure mobilization offer advantages in postoperative recovery and reduced morbidity compared to open surgery but pose greater challenges due to limited visibility and instrument maneuverability at the splenic flexure, resulting in higher conversion rates (up to 10-15% in complex cases). Open techniques provide direct access for safer dissection in adherent or bulky but are associated with longer hospital stays and increased wound complications. Overall, the choice of approach depends on surgeon expertise and patient factors, with hybrid methods increasingly adopted to balance feasibility and outcomes.