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Internal hernia
Internal hernia
Internal hernia
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Internal hernia
Diagram of a hernia: a loop of bowel protruding through a hole in tissue
A hernia—the hole in the light-colored wall of tissue—can trap loops of the bowel or other tissue
SpecialtyGeneral surgery
Differential diagnosisEndometriosis, chronic pelvic pain

Internal hernias occur when there is protrusion of an internal organ into a retroperitoneal fossa or a foramen (congenital or acquired) in the abdominal cavity. If a loop of bowel passes through the mesenteric defect, that loop is at risk for incarceration, strangulation, or for becoming the lead point of a small bowel obstruction.[1] Internal hernias can also trap adipose tissue (fat) and nerves. Unlike more common forms of hernias, the trapped tissue protrudes inward, rather than outward.[2]

Mesenteric defects commonly occur in trauma, such as gunshot wounds to the abdomen. In trauma victims, the defect is usually closed, sometimes with resection of the associated bowel, which may have lost its blood supply.[1] Also mesenteric defects are intentionally created in the Roux-en-Y gastric bypass procedure, being classically known as a Petersen's hernia.[3] The mesenteric defect in such cases, called Petersen's defect, is located between the transverse colon and the mesentery of the alimentary limb (the segment of the jejunum from the jejunojejunostomy until the connection with the proximal segment of the stomach) at the level of the jejunojejunostomy.[4]

Internal hernias are difficult to identify in women, and misdiagnosis with endometriosis or idiopathic chronic pelvic pain is very common. One cause of misdiagnosis that when the woman lies down flat on an examination table, all of the medical signs of the hernia disappear. The hernia can typically only be detected when symptoms are present, so diagnosis requires positioning the woman's body in a way that provokes symptoms.

Both internal hernias and umbilical hernias are more common in women than men.[2]

References

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Internal hernia

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An internal hernia is the protrusion of abdominal viscera, most commonly loops of small bowel, through a defect or aperture in the or within the , without involving the external . These hernias are classified into several types based on the location of the defect, with paraduodenal hernias being the most common, accounting for approximately 53% of cases, followed by pericecal (13%), of Winslow (8%), and transmesenteric (8%). They can be congenital, arising from developmental anomalies such as abnormal rotation of the , or acquired, often resulting from prior (e.g., Roux-en-Y gastric bypass or ), trauma, , or increased intra-abdominal pressure from conditions like or chronic coughing. Clinically, internal hernias present a diagnostic challenge due to their nonspecific symptoms, which range from incidental findings to acute abdominal emergencies. Common manifestations include intermittent or colicky , , , , and , with severe cases progressing to , ischemia, or strangulation, the latter carrying a exceeding 50% if untreated. relies primarily on multidetector computed (MDCT), which demonstrates high sensitivity (94-100%) and specificity (90-95%) through signs such as clustered small bowel loops, mesenteric vessel swirling (e.g., the "whirl sign"), and displacement of adjacent structures like the or . Traditional may show nonspecific features like dilated bowel loops or air-fluid levels, but it is less reliable. Management is predominantly surgical, as conservative approaches with bowel rest and fluids are reserved for mild, reducible cases without complications. Laparoscopic or open reduction of the herniated contents, with closure of the defect, is the standard intervention to prevent recurrence and , particularly in postoperative settings where mesenteric defects from bariatric procedures are a growing . Overall, internal hernias are rare, comprising 0.5-5.8% of all small bowel obstructions, but their incidence is rising with the prevalence of surgeries, underscoring the need for vigilant postoperative monitoring.

Overview

Definition

An internal hernia is defined as the protrusion of abdominal viscera, most commonly small bowel loops, through a normal or abnormal or mesenteric within the or , without breaching the . This condition occurs entirely internally within the and can involve any abdominal organ, although the is affected in the majority of cases. A key characteristic is the potential for closed-loop obstruction, in which a segment of bowel is entrapped and occluded at two adjacent points along its course, heightening the risk of strangulation and ischemia. Internal hernias were first described in 1742 by anatomist Friedrich Wilhelm Hensing in a case of paraduodenal herniation during early 18th-century anatomical studies. Their modern recognition has been advanced by surgical developments, including the proliferation of bariatric procedures like Roux-en-Y gastric bypass, which have increased the incidence of iatrogenic internal hernias by creating mesenteric defects. Unlike external hernias, internal hernias typically lack a peritoneal sac enclosing the herniated contents, yet they are classified as hernias owing to the analogous of visceral protrusion through a congenital or acquired defect.

Epidemiology

Internal hernias are a rare condition, with an incidence ranging from 0.2% to 0.9%. They account for 0.6% to 5.8% of all cases of . In the context of post-bariatric , particularly laparoscopic Roux-en-Y gastric bypass, the incidence is higher, reported between 0.2% and 8.6%, with cumulative rates reaching approximately 4.8% by the third postoperative year. Demographically, internal hernias show no strong overall age or predilection, though presentations often occur in adulthood with a age around 32 years and a male-to-female ratio of roughly 4:3. Congenital forms, such as paraduodenal hernias, exhibit a slight male predominance with a ratio of 3:1. Acquired cases following are more frequent in females, reflecting the higher of bariatric procedures among women. Reports of internal hernias have increased since the early , attributable to the global rise in laparoscopic bariatric procedures; however, recent data indicate a decreasing trend in incidence following improvements in surgical techniques. Congenital variants are occasionally identified as incidental findings in up to 0.9% of autopsies, underscoring their underdiagnosis during life. Geographic variations are limited in data, but higher incidences align with regions of advanced surgical access for bariatric interventions, such as and . When strangulation occurs, mortality rates for internal hernias range from 20% to 50%.

Classification

Congenital Types

Congenital internal hernias arise from developmental anomalies in the peritoneal attachments and fossae, leading to defects through which abdominal viscera may protrude while remaining within the . These hernias account for a significant portion of noniatrogenic internal herniations and are classified based on the specific peritoneal recess or mesenteric defect involved. The most common subtypes include paraduodenal, pericecal, , and intersigmoid hernias, with rarer variants such as supravesical and pelvic types. Paraduodenal hernias represent the most prevalent congenital type, comprising approximately 53% of all internal hernias. They occur due to incomplete rotation of the during embryonic development, resulting in clustering of small bowel loops behind the mesocolon through pre-existing fossae. Left paraduodenal hernias, which account for about 75% of this subtype, protrude through Landzert's fossa—a peritoneal recess located posterior to the descending mesocolon near the duodenojejunal junction—and are more common in males with a 3:1 ratio. Right paraduodenal hernias, making up the remaining 25%, involve herniation through Waldeyer's fossa, inferior to the third portion of the , and encase small bowel loops within a sac formed by the . Pericecal hernias constitute 10-13% of congenital internal hernias and develop through defects in the cecal or appendiceal orifices, often involving the ileocecal region. These are subdivided into para-cecal (through the lateral paracolic sulcus or superior ileocecal recess), retrocecal (posterior to the ), and ileocecal (through the inferior ileocecal recess) subtypes, each reflecting variations in peritoneal fusion during fetal development. The herniated small bowel typically forms a sac-like cluster that displaces the or anteriorly or medially, increasing the risk of strangulation. Foramen of Winslow hernias, accounting for about 8% of cases, occur through the epiploic foramen—a normal anatomical communication between the greater and lesser peritoneal sacs, situated beneath the hepatoduodenal ligament. This defect allows herniation of viscera such as the small bowel, right colon, or even the gallbladder into the lesser sac, often triggered by increased intra-abdominal pressure. The anatomy involves the portal vein, hepatic artery, and common bile duct forming the anterior boundary, with the inferior vena cava posteriorly. Intersigmoid hernias comprise 5-10% of congenital internal hernias and arise through the intersigmoid fossa, a peritoneal recess in the sigmoid mesocolon present in up to 65% of individuals at . Predominantly left-sided, these hernias involve protrusion of the small bowel into a sac bounded by the attachments, leading to potential of the sigmoid mesentery. They are often incidental but can cause intermittent obstruction. Rarer congenital variants include supravesical hernias, which occur through the supravesical fossa anterior to the and bounded by the umbilical ligaments, and pelvic hernias, such as those through defects in the in females. Supravesical hernias, part of the approximately 6% of pelvic and supravesical cases combined, allow small bowel loops to enter the , compressing the . Broad ligament hernias, the most common pelvic subtype, involve fenestrations in the lateral to the , often seen in multiparous women and accounting for 4-7% of internal hernias overall. These defects may be unilateral or bilateral, stemming from incomplete müllerian duct fusion.

Acquired Types

Acquired internal hernias develop from defects in the or resulting from prior , trauma, or , distinguishing them from congenital variants. With the rise in abdominal surgeries, particularly laparoscopic procedures, acquired types now constitute the majority of internal hernias, surpassing congenital forms in overall frequency. These hernias lack a true peritoneal sac and often lead to if untreated, accounting for up to 5.8% of such cases despite an overall incidence below 1%. Transmesenteric hernias represent a common acquired subtype, involving protrusion of small bowel loops through iatrogenic defects in the small bowel , frequently following surgeries such as bowel resection, Roux-en-Y gastric bypass, or . These defects typically arise from incomplete closure of mesenteric incisions during procedures, leading to clustered bowel loops and potential . Historically comprising about 8% of all internal hernias, their incidence has increased to 0.7-3.25% after laparoscopic Roux-en-Y gastric bypass, with one series reporting them in 57% of nonbariatric acquired cases. Clinical presentation includes acute periumbilical pain, , and distention, often without prominent due to partial obstruction. Post-bariatric hernias have seen a notable rise with the expansion of procedures like -en-Y gastric bypass, occurring through spaces such as Petersen space (behind the limb) or mesojejunal defects if mesenteric defects remain unclosed. The overall incidence of internal hernias after laparoscopic gastric bypass ranges from 0.2% to 9%, with Petersen hernias specifically reported in up to 6.2% of cases without defect closure. These often present insidiously with chronic or acute obstruction, exacerbated by the altered anatomy that facilitates bowel migration. Traumatic internal hernias are rare acquired forms, resulting from blunt that tears the , creating apertures for bowel herniation without prior surgical history. Such defects mimic transmesenteric types radiographically but stem from shear forces during , with incidence not precisely quantified but contributing to the broader category of acquired hernias at less than 1% overall. Symptoms typically manifest as delayed , highlighting the need for vigilant post-trauma . Other acquired variants include retroanastomotic hernias, which occur posterior to a gastrojejunal following or similar reconstructions, historically noted in about 5% of cases and often within the first postoperative month. These arise from spaces created by the surgical reconfiguration, allowing jejunal loops to herniate and potentially strangulate. Additionally, acquired defects through diaphragmatic openings, such as iatrogenic hiatal variants, can permit internal herniation of abdominal viscera, though these remain uncommon and are linked to prior thoracic-abdominal interventions.

Anatomy and Pathophysiology

Relevant Anatomy

Internal hernias involve the protrusion of abdominal viscera through various peritoneal fossae, recesses, or apertures within the . Key sites include the paraduodenal fossae, which are located in the upper near the . The left paraduodenal fossa, also known as Landzert's fossa, is situated posterior to the fourth portion of the and lateral to the ascending branch of the left colic artery, formed by incomplete fusion of the descending mesocolon during embryonic development. This fossa serves as a potential space bounded by the covering the posterior . The right paraduodenal fossa, or Waldeyer's fossa, lies inferior to the third portion of the and posterior to the , bordered by the of the and the . Other significant peritoneal apertures include the foramen of Winslow, also called the epiploic foramen, which connects the greater and lesser peritoneal sacs and is bordered anteriorly by the hepatoduodenal ligament (containing the , , and hepatic artery), posteriorly by the , superiorly by the caudate lobe of the liver, and inferiorly by the . The intersigmoid fossa is a V-shaped peritoneal recess located at the base of the sigmoid mesocolon, between its two layers of , and opens medially toward the left . Pericecal recesses, situated in the right lower quadrant, encompass several subtypes such as the superior ileocecal, inferior ileocecal, retrocecal, and paracolic fossae, primarily behind the and , limited by the cecal and . The and omentum provide structural support and potential sites for herniation due to their attachments and variable defects. The small bowel is a fan-shaped fold attaching along a line from the (ligament of Treitz) to the ileocecal junction, with its root oriented obliquely along the and vein, measuring approximately 15-20 cm in length. Congenital or acquired defects in this , often near the terminal ileum or ligament of Treitz, create apertures through which bowel loops may protrude, altering the normal intraperitoneal positioning. The , a double-layered peritoneal fold extending from the greater curvature of the , drapes over the and small bowel, but its mobility can contribute to entrapment in adjacent fossae. In females, the broad ligament of the , a double layer of extending from the lateral uterine margins to the pelvic sidewalls, encloses the ovaries, fallopian tubes, and round ligaments, with potential fenestrations or defects allowing herniation of pelvic viscera, particularly small bowel loops lateral to the . Vascular structures at the mesenteric root play a critical role in the implications of herniation sites. The arises from the at the L1 level and courses along the mesenteric root, branching to supply the from the distal to the splenic flexure, while the parallels it, draining into the . At sites of herniation, such as paraduodenal fossae or mesenteric defects, these vessels can become crowded or stretched, predisposing to twisting and , which compromises blood flow to the herniated bowel. Normal anatomical variants, such as incidental peritoneal or mesenteric openings, occur in a subset of the population and may predispose to herniation without symptoms until an event triggers protrusion. Landzert's fossa is present in approximately 2% of individuals, while Waldeyer's fossa is found in less than 1%. The intersigmoid fossa exists in 50-80% of autopsies, though herniation through it remains rare due to its configuration. Congenital mesenteric defects, including small openings in the small bowel mesentery, are identified in autopsy series at rates of 0.2-0.9%, providing silent pathways for potential internal herniation.

Mechanisms of Herniation

Internal hernias occur when segments of the small bowel or other viscera protrude through congenital or acquired defects in the or , driven by the combined forces of intestinal and intra-abdominal pressure gradients that propel bowel loops toward and through these apertures. This migration often results in the formation of a closed-loop configuration, where the herniated bowel becomes trapped between the defect's entry and exit points, preventing spontaneous reduction and leading to progressive entrapment. The process is exacerbated in postoperative settings, such as after Roux-en-Y gastric bypass, where mesenteric defects facilitate this abnormal displacement. Obstruction in internal hernias typically arises through mechanical means, such as kinking of the bowel at the narrow of the defect, which impedes luminal flow and causes proximal dilation. Vascular compromise frequently accompanies this, manifesting as strangulation due to twisting or compression of the , which restricts arterial inflow and venous drainage in approximately 25% of closed-loop obstructions. , a rotational twisting of the bowel around its , contributes to this in a subset of cases, further tightening the loop and accelerating obstructive effects. The ischemia pathway begins with mesenteric vessel compression, leading to bowel wall from impaired venous return and subsequent arterial , which can progress to transmural if unrelieved for more than 6 hours. Increased intraluminal within the trapped segment exacerbates incarceration by promoting sequestration and distension, creating a vicious cycle of worsening obstruction. The clinical course may be intermittent for larger defects that allow partial reduction, but smaller defects often lead to progressive, unrelenting incarceration with higher risks of strangulation.

Etiology and Risk Factors

Causes

Internal hernias arise from defects in the or that allow protrusion of abdominal viscera, with etiologies broadly categorized as congenital, iatrogenic, traumatic, or other. Congenital causes stem from failures in embryologic development, particularly incomplete rotation and fixation of the , leading to persistent peritoneal fossae or mesenteric defects. For instance, paraduodenal hernias, the most common congenital type, result from abnormal rotation during embryogenesis, preventing obliteration of fossae such as Landzert's (left) or Waldeyer's (right), with left-sided variants accounting for about 75% of cases. These defects occur in approximately 2% of the population for Landzert's fossa and less than 1% for Waldeyer's. Other congenital anomalies include pericecal or intersigmoid fossae that fail to fuse properly, predisposing to herniation of ileal segments or small bowel loops. Iatrogenic causes predominate in adults and involve surgically induced mesenteric or peritoneal defects, often from gastrointestinal procedures that create potential spaces without closure. Common examples include transmesenteric defects following Roux-en-Y gastrojejunostomy or , where unclosed gaps allow bowel herniation; in one series, 69% of internal hernias were linked to prior surgery. In , such as laparoscopic Roux-en-Y gastric bypass, non-closure of mesenteric defects contributes to internal hernias in 0.2% to 8.6% of cases, with cumulative incidence reaching up to 5% by three years post-procedure; as of 2025, rates remain similar at 0.5-11% depending on defect closure practices. Retroanastomotic hernias also occur post-gastrectomy or similar operations, with rates of 0.7% to 3.25% reported after laparoscopic approaches. Traumatic causes involve disruption of mesenteric integrity from blunt abdominal , leading to tears or defects that permit herniation, as seen in up to 5% of intestinal obstruction cases post-trauma. Examples include seatbelt-related injuries causing transmesenteric defects or post-traumatic adhesions that widen existing apertures. Inflammatory processes, such as , can similarly induce adhesions or erode peritoneal barriers, creating acquired defects; these account for a subset of adult-onset internal hernias alongside trauma. Other etiologies are less common and include idiopathic mesenteric apertures without prior trauma or , such as spontaneous transverse mesocolon defects leading to herniation. Rare instances involve peritoneal from tumors or vascular diseases, though these are infrequently reported as primary causes.

Risk Factors

Internal hernias are associated with several non-modifiable and modifiable factors that predispose individuals to mesenteric or peritoneal defects allowing bowel herniation. Surgical history represents a primary non-modifiable , particularly prior abdominal operations that create potential spaces for herniation. Laparoscopic bariatric procedures, such as Roux-en-Y gastric , carry a notably elevated , with internal hernia incidence reported between 0.2% and 8.6% in post-operative patients. The laparoscopic approach itself amplifies this susceptibility compared to open , with studies indicating an approximately five-fold increased odds in related gastrointestinal procedures like . Adhesiolysis during prior surgeries can further contribute by forming iatrogenic defects in the . Organ , including liver and procedures, also heightens due to reconstructive techniques that may leave unclosed mesenteric gaps, leading to reported cases of internal herniation. Demographic factors similarly influence vulnerability. , often defined by a BMI exceeding 40 kg/m², indirectly elevates post-operative risk for internal in bariatric patients through mechanisms like rapid excess , which reduces mesenteric fat and enlarges potential hernia spaces. Age-related tissue weakening may contribute to susceptibility, though specific for internal hernias remain limited. gender confers particular risk for pelvic variants, such as broad hernias, which occur exclusively in women and account for about 4% of all internal hernias. Modifiable lifestyle factors include chronic , which elevates intra-abdominal pressure and may precipitate herniation through existing defects. Pregnancy represents another modifiable risk, particularly for broad ligament hernias, as it induces ligament stretching and increased abdominal pressure that can create or widen congenital or acquired openings. Comorbidities involving tissue integrity further compound risk. Connective tissue disorders can weaken mesenteric and peritoneal structures, predisposing to herniation alongside other abdominal defects. Inflammatory bowel disease contributes via chronic mesenteric inflammation and surgical interventions that compromise tissue strength, increasing the likelihood of internal hernias as a cause of .

Clinical Manifestations

Symptoms

Internal hernias often present with a spectrum of symptoms ranging from asymptomatic to acute and life-threatening manifestations, depending on the degree of bowel involvement and presence of complications such as obstruction or strangulation. In acute cases, patients typically experience sudden onset of severe abdominal pain, which may be colicky or localized to the epigastric or periumbilical region, accompanied by nausea and bilious vomiting due to small bowel obstruction, as well as abdominal bloating from distension. Chronic or intermittent symptoms are more subtle, including vague postprandial discomfort and recurrent episodes of partial , which can mimic other gastrointestinal disorders. Many internal hernias remain asymptomatic until a complication arises, contributing to delayed . When complete obstruction occurs, symptoms progress to include or obstipation along with progressive . In instances of strangulation, the pain intensifies to a constant, peritonitis-like severity, reflecting ischemic bowel changes as described in the of herniation. Atypical presentations may involve referred , particularly in retroperitoneal internal hernias.

Physical Examination Findings

The of patients with internal hernia typically reveals findings consistent with small bowel obstruction, but notably lacks an externally visible or palpable hernia bulge, distinguishing it from external hernias. Abdominal inspection often shows distension due to accumulated gas and fluid in the bowel, while percussion elicits tympany over distended loops; may demonstrate diffuse tenderness or localized guarding, particularly if ischemia or develops, though peritoneal signs like rebound tenderness are less common in uncomplicated cases. Auscultation of bowel sounds is a key component, with hyperactive, high-pitched, or tinkling sounds indicative of early mechanical obstruction from herniated bowel; in advanced stages with or strangulation, sounds become hypoactive or absent. frequently include reflecting pain or , and fever may occur in the presence of strangulation or ; signs of , such as dry mucous membranes, reduced skin turgor, and sunken eyes, are common secondary to and fluid sequestration. Rarely, a palpable intra-abdominal may be appreciated in thin or cachectic patients, as reported in cases of paraduodenal or pericecal hernias, where the clustered herniated bowel loops can form a detectable fullness in the left upper or right lower quadrant, respectively. In chronic or recurrent presentations, a scaphoid may be observed due to protracted or volume depletion, though this is nonspecific.

Diagnosis

Clinical Evaluation

Clinical evaluation of internal hernia begins with a thorough to identify potential risk factors and symptom patterns suggestive of small bowel obstruction (SBO), a common presentation of this condition. Emphasis is placed on prior abdominal surgeries, such as Roux-en-Y gastric bypass or other procedures that may create mesenteric defects, as these are key predisposing factors for acquired internal hernias. Patients should be screened for symptom timeline, distinguishing acute onset (often within hours to days, indicating mechanical obstruction) from chronic or intermittent episodes, which may reflect partial herniation. Additional risk factors, including rapid postoperative or congenital anomalies like mesenteric malrotation, should be elicited to guide suspicion. Laboratory tests play a supportive role in assessing for complications like ischemia or . (CBC) often reveals , particularly in cases of bowel strangulation or ischemia, signaling inflammation or infection. Electrolyte panels may show due to prolonged , a frequent symptom in proximal SBO from internal hernia. Serum lactate levels are particularly valuable; elevations greater than 2 mmol/L are predictive of strangulation. These findings help stratify urgency but are not diagnostic alone. Differential diagnosis for suspected internal hernia centers on causes of SBO, where adhesions account for approximately 60-70% of cases, while external hernias account for approximately 15-20% and internal hernias for 0.5-5% of cases. Other considerations include , characterized by right lower quadrant pain and fever, and , which may present with epigastric pain radiating to the back and elevated . may reveal abdominal tenderness or distension, though findings are often nonspecific. Scoring systems like the Alvarado score, originally for appendicitis, have been adapted for broader acute abdominal pain evaluation but demonstrate low specificity for internal hernias due to overlapping features with other SBO etiologies.

Imaging Modalities

Computed tomography (CT) is considered the gold standard imaging modality for diagnosing internal hernias, with reported sensitivity for key signs ranging from 61% to 100%, though pooled overall sensitivity is approximately 82% in postoperative cases depending on the clinical context and reviewer experience. Key CT findings include the mesenteric swirl sign, characterized by a whirl-like twisting of mesenteric vessels and fat around the superior mesenteric artery axis; clustered or encapsulated jejunal loops in an abnormal location; engorged and crowded mesenteric vessels; and a transition point at the hernial defect, often marked by beaking or abrupt caliber change in bowel loops. These features are particularly useful in postoperative settings, such as after bariatric surgery, where internal hernias are a common complication. Magnetic resonance imaging (MRI) serves as an alternative in equivocal cases or when is a concern, such as in pediatric patients. It can demonstrate the whirlpool sign, similar to CT, with swirling loops of bowel and visible on T2-weighted sequences, providing detailed contrast without . However, MRI is less commonly used in acute settings due to longer scan times and limited availability. Ultrasound is a limited, operator-dependent modality primarily useful for initial screening to detect free intraperitoneal fluid or bowel wall thickening suggestive of obstruction. Color Doppler assessment can evaluate vascular flow in mesenteric vessels, helping identify potential compromise, but its deep penetration is hindered in adults, making it more feasible in thin patients or children. Plain abdominal radiography is nonspecific and typically shows signs of small , such as multiple air-fluid levels in approximately 50% of cases, but it cannot confirm the presence of an internal hernia and is mainly used to exclude or other acute abdominal emergencies. In cases of suspected vascular compromise, CT angiography may be employed to assess mesenteric vessel patency and ischemia more precisely. If imaging remains inconclusive, diagnostic can provide definitive evaluation and allow for immediate intervention. As of 2025, emerging radiomics-based models applied to CT scans show promise for improving diagnostic accuracy in detecting internal hernias.

Management

Conservative Management

Conservative management is generally not recommended for suspected internal hernias due to the high risk of strangulation and ischemia, with guidelines advising prompt surgical exploration even in stable patients. It may be considered only for incidental findings without obstruction or symptoms, or in very mild cases without evidence of ischemia (e.g., normal serum lactate levels and stable ) and typically when symptoms have lasted less than 24 hours to minimize strangulation risk. This approach aims to allow potential spontaneous reduction while avoiding unnecessary in low-risk cases. Key measures include keeping the patient nil per os (NPO) to rest the bowel, intravenous fluid with isotonic solutions (such as lactated Ringer's) to correct and imbalances, nasogastric tube decompression to relieve distension and , and administration of analgesics for symptom control. Close monitoring involves serial abdominal examinations, repeated laboratory assessments (including white blood cell count and lactate), and vital sign checks every 4-6 hours to detect deterioration. If no improvement occurs within 48 hours, repeat imaging such as CT is recommended to reassess; broad-spectrum antibiotics (e.g., piperacillin-tazobactam) should be initiated if or is suspected based on fever or rising inflammatory markers. Success rates for conservative management in suspected internal hernias are not well-established due to the preference for , but in general small bowel obstructions, resolution occurs in 40-70% of partial cases without closed-loop features, often within 72 hours; however, this is lower and riskier for internal hernias. Failure, indicated by worsening pain or imaging findings, necessitates prompt surgical escalation.

Surgical Interventions

The laparoscopic approach is the preferred method for surgical intervention in internal hernias due to its minimally invasive nature, lower morbidity, and high success rates, with conversion to open occurring in less than 10% of cases when standardized techniques are employed. This involves initial exploration to identify the herniated bowel, gentle reduction of the contents to avoid , and assessment of bowel viability through inspection for color, , and pulsation. If viable, the defect is closed using non-absorbable running sutures, such as 2-0 Ethibond, often leaving a small 5-10 mm gap to prevent excessive tension; in post-bariatric cases, particular attention is given to closing Petersen's space and the mesojejunal defect. reinforcement may be used for larger defects, though primary suture closure remains standard to minimize infection risk. Open surgery is reserved for complex cases with extensive adhesions, strangulation, or hemodynamic instability, where direct visualization facilitates management of multiple defects or massive bowel involvement. In such scenarios, allows for thorough of adhesions and resection of necrotic bowel, which is required in approximately 50% of cases with compromised bowel. Bowel viability is evaluated intraoperatively, with second-look recommended 24-48 hours later for borderline cases to confirm reperfusion. Surgical techniques vary by hernia type to address specific anatomical defects. For paraduodenal hernias, the most common congenital variant, reduction of the herniated small bowel is followed by division of the paraduodenal sac or peritoneal folds, with defect closure using interrupted sutures or, in cases of malrotation, Ladd's procedure involving band division and cecum repositioning to widen the orifice and prevent recurrence. Mesenteric hernias, often acquired post-surgery, require plication or imbrication of the mesenteric defect after reduction, using continuous non-absorbable sutures to narrow the aperture without compromising vascular supply. Intraoperative assessment of viability remains critical across types, guiding decisions on resection. Timing of intervention is emergent in cases of or suspected strangulation to limit ischemia, with delays beyond 3 days associated with higher mortality. Prophylactic closure of potential defects during high-risk procedures, such as Roux-en-Y gastric bypass, significantly reduces internal hernia incidence by approximately 70%, as recommended by the American Society for Metabolic and Bariatric Surgery (ASMBS) guidelines (as of 2023).

Complications

Acute Complications

One of the most immediate and life-threatening acute complications of internal hernias is bowel strangulation, which occurs when the herniated intestinal segment becomes trapped and its blood supply is compromised, leading to ischemia and potential . This complication arises in a significant proportion of symptomatic internal hernias, with rates exceeding 50% in certain subtypes such as paraduodenal hernias over a lifetime. Symptoms typically include severe and elevated serum lactate levels, reflecting tissue hypoperfusion and early ischemic changes. If untreated, strangulation progresses rapidly to full-thickness bowel wall , necessitating emergent intervention to prevent further deterioration. Perforation of the bowel represents another critical acute , often resulting directly from ischemic damage in strangulated segments, which compromises the intestinal wall integrity and allows contents to spill into the , triggering diffuse . This condition is associated with high morbidity, as the resulting chemical and bacterial can evolve into , carrying a of approximately 30-50% in severe cases. The process is exacerbated by the closed nature of internal hernia defects, which delay and containment of contamination. Volvulus frequently complicates internal hernias, particularly transmesenteric types, where the herniated bowel twists around its at the defect site, creating a closed-loop obstruction that severely restricts vascular flow and accelerates progression to . This twisting mechanism heightens the risk of ischemia, with reports indicating a high incidence of strangulation and in affected loops due to the mechanical compression and venous occlusion. The rapid onset distinguishes volvulus as a peracute event, often manifesting within hours of herniation. Sepsis emerges as a systemic acute complication when bacterial translocation from ischemic or perforated bowel overwhelms host defenses, eliciting a dysregulated inflammatory response that can lead to multi-organ failure. In internal hernia cases, this is driven by gut barrier disruption, with overall mortality exceeding 50% in strangulated presentations complicated by . Risk factors include underlying diabetes mellitus, which impairs immune function and , thereby amplifying susceptibility to bacterial dissemination and septic progression.

Long-term Complications

One of the primary long-term complications following repair of an internal hernia is recurrence, which occurs in approximately 5-15% of cases depending on surgical technique and defect management. In a of patients undergoing laparoscopic Roux-en-Y gastric bypass with internal herniation repair, the recurrence rate was 14% over a follow-up of 75 months, with all recurrences happening at untreated mesenteric gaps rather than the repaired site. This risk increases significantly if mesenteric defects are left unclosed during initial bariatric procedures; a reported an internal hernia rate of 6% in non-closure cases compared to 2% with closure, highlighting the importance of comprehensive defect closure to mitigate recurrent herniation. Post-surgical adhesions represent another common long-term issue after internal hernia repair, particularly in contexts, where they can cause chronic or predispose to future small bowel obstructions. Adhesions form as bands between abdominal organs, often exacerbated by the inflammatory response to , and may lead to intermittent symptoms years later. In patients undergoing reoperation for or obstruction after Roux-en-Y gastric bypass, over 45% of cases were attributed to adhesions, underscoring their role in delayed morbidity. Short bowel syndrome is a severe long-term complication that arises when extensive small bowel resection is required due to ischemia or during internal hernia episodes, resulting in and nutritional deficits. This condition is particularly noted in patients, where internal herniation can necessitate significant bowel removal; however, the overall risk remains low at approximately 0.01% following Roux-en-Y gastric bypass, though affected individuals often face lifelong dependence on or supplementation. Nutritional challenges, including deficiencies in vitamins and electrolytes, are common following significant resection, emphasizing the need for vigilant postoperative monitoring. Incisional hernia, an external manifestation of long-term weakness, develops in patients who undergo open surgical access for internal hernia repair. Rates vary but typically range from 2-20% after midline , driven by factors such as , , and poor tissue healing. In bariatric populations, this complication can compound mobility issues and require additional interventions, further impacting .

Prognosis and Prevention

Prognosis

The prognosis for internal hernia is generally favorable when diagnosed early and managed surgically, with overall mortality rates reported as low as 2% and morbidity around 12% in large nonbariatric series. Delayed diagnosis, particularly in cases involving strangulation, significantly worsens outcomes, with mortality rates ranging from 20% to 50%. For instance, intervention beyond 24 hours in strangulated cases can elevate mortality to 25%, compared to 8.3% with prompt treatment. Several factors influence recovery and . Younger age, specifically under 50 years, is associated with improved outcomes, as older patients face a threefold higher mortality risk ( 3.35). Timely surgical intervention remains critical, with delays exceeding three days increasing mortality odds by over 13-fold due to risks like intestinal . Postoperative recurrence further affects , occurring in up to 14% of cases, often at untreated mesenteric defects, and leading to repeated obstructions or chronic discomfort. In the long term, bariatric patients experience elevated morbidity following repair, with approximately 4% developing chronic and up to 56% requiring evaluations for persistent issues. Advances in computed for early detection and laparoscopic techniques have contributed to overall prognostic improvements, reducing historical high mortality rates associated with delayed diagnosis.

Prevention Strategies

Surgical prevention of internal hernias primarily involves meticulous closure of mesenteric defects during bariatric and intestinal surgeries, such as laparoscopic Roux-en-Y gastric bypass (LRYGB), to minimize the risk of small bowel protrusion. A of observational studies involving over 20,000 patients demonstrated that routine closure of these defects reduces the incidence of internal hernias from 6% in non-closure cases to 2% in closure cases, representing a of approximately 67%. Similarly, a confirmed that defect closure with clips during LRYGB significantly lowers the long-term rate of internal herniation compared to non-closure. A 2025 Cochrane review further supports that closure during Roux-en-Y gastric bypass reduces the incidence of internal hernia with within 10 years compared with non-closure. The use of anti-adhesive barriers, such as hyaluronate-based membranes, may further aid in preventing -related complications that could contribute to formation in abdominal surgeries, though evidence is stronger for general adhesion prevention than specifically for internal hernias. Lifestyle modifications play a supportive role in reducing the overall risk, particularly for patients with obesity-related predispositions. Postoperatively, patients are advised to avoid high-risk activities, including heavy lifting exceeding 15-20 pounds, for at least 6 weeks to allow proper healing of surgical sites and reduce mechanical stress on mesenteric structures. Screening protocols for at-risk populations, such as those undergoing bariatric procedures, emphasize on early symptoms like intermittent or to prompt timely evaluation. While routine computed tomography (CT) imaging at 6-12 months is not universally recommended due to variable diagnostic sensitivity (30-100%), it may be considered for high-risk patients, such as those with unclosed defects or concerns, to detect hernias early. Ongoing explores advanced preventive measures, including the prophylactic placement of in mesenteric defects to reinforce closures and further mitigate recurrence risks, though long-term outcomes remain under investigation.

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