Fact-checked by Grok 2 weeks ago

Small intestine

The small intestine, also known as the small bowel, is a vital component of the human digestive system, consisting of a long, coiled tubular structure primarily responsible for the chemical breakdown of food and the absorption of nutrients, water, and electrolytes into the bloodstream. It extends from the pylorus of the stomach to the ileocecal valve, where it connects to the large intestine, and is housed within the abdominal cavity, framed by the large intestine. In adults, the small intestine measures approximately 6 to 7 meters (20 to 23 feet) in length, with a diameter of about 2.5 to 3 centimeters, making it the longest segment of the gastrointestinal tract despite its name. The small intestine is anatomically divided into three distinct regions: the , , and , each with specialized roles in and . The , the shortest section at about 25 to 30 centimeters, forms a C-shaped curve around the head of the and serves as the site for initial neutralization of acidic from the via bicarbonate secretions, while also absorbing iron and . The , comprising roughly two-fifths of the small intestine's length (approximately 2.5 meters), is primarily responsible for the absorption of carbohydrates, proteins, and fats, featuring prominent circular folds (plicae circulares) and villi that greatly increase its surface area. The , the longest portion at about 3 to 3.5 meters, connects to the and specializes in absorbing , bile salts, and remaining nutrients, while housing lymphoid tissue such as Peyer's patches for immune surveillance. Structurally, the small intestine's wall consists of four layers—mucosa, , muscularis externa, and serosa—that facilitate its functions, with the mucosa lined by villi and microvilli that expand the absorptive surface area by up to 600-fold to about 200 square meters. Its functions extend beyond nutrient processing to include endocrine activities, such as hormone secretion (e.g., and cholecystokinin) that regulate , and contributions to gut immunity through the . Blood supply is provided mainly by the for the jejunum and ileum, and by pancreaticoduodenal arteries for the duodenum, while innervation from the (parasympathetic) enhances motility and secretion, and sympathetic fibers from modulate these processes. Overall, the small intestine processes up to 9 liters of fluid daily, absorbing over 90% of nutrients and water, underscoring its critical role in maintaining nutritional and overall .

Structure

Length and diameter

The small intestine in adult humans measures approximately 3 to 5 meters in length when assessed in living individuals, such as through surgical or techniques, though postmortem measurements often yield longer values of 6 to 7 meters due to the loss of tone and subsequent relaxation and uncoiling of the organ. This discrepancy arises because the intestine maintains a degree of contraction , influenced by peristaltic activity and neural control, whereas fixation or relaxation post-mortem extends its apparent length. The organ is divided into three regions with distinct lengths: the , averaging about 25 cm; the , roughly 2.5 meters; and the , approximately 3 to 3.5 meters, though these proportions can vary slightly based on individual . The of the small intestine typically ranges from 2.5 to 3.5 cm, with a gradual decrease observed from the proximal to distal segments: the is the widest at around 2.5 cm, the maintains a similar caliber of about 2.4 to 2.5 cm, and the narrows to approximately 2 cm. This tapering facilitates the progressive adaptation to nutrient processing and along its . and are influenced by factors such as , , and ; for instance, the small intestine tends to be longer in males than in females, correlates positively with height and weight, and may shorten slightly with advancing due to atrophic changes. Measurements are commonly obtained via noninvasive imaging modalities like computed tomography () scans, which provide assessments, or through for postmortem evaluation, ensuring accuracy by accounting for the organ's coiled configuration within the . Although the gross dimensions provide a baseline tubular structure, the small intestine's effective surface area for is dramatically amplified by structural adaptations, reaching approximately 200 m²—comparable to the size of a —through the combined effects of plicae circulares (circular folds), villi, and microvilli. Plicae circulares increase the surface by about threefold, villi contribute an additional tenfold amplification by projecting into the , and microvilli on enterocytes further multiply this by roughly twentyfold, enabling efficient uptake over the organ's limited physical . This extensive interfacial area underscores the small intestine's critical role in efficiency, as detailed in subsequent sections on .

Regions

The small intestine is anatomically divided into three distinct regions: the , , and , which extend from the of the to the ileocecal junction. These regions differ in their , peritoneal attachments, and structural features, facilitating their specialized roles within the digestive tract. The , the shortest and most proximal region, measures approximately 25 cm in length and forms a C-shaped curve around the head of the . It is primarily retroperitoneal, fixed to the posterior , with only its initial 2–3 cm being intraperitoneal. The is subdivided into four parts: the superior (first) part, which extends from the ; the descending (second) part, which receives the openings of the and pancreatic ducts at the major duodenal papilla () and minor duodenal papilla; the horizontal (inferior or third) part; and the ascending (fourth) part, which ascends to meet the . This region is distinguished by the presence of submucosal , which are absent in the more distal segments. The jejunum constitutes the proximal two-fifths of the remaining small intestine (excluding the duodenum) and is approximately 2.5 meters long. It begins at the duodenojejunal flexure, suspended by the ligament of Treitz, and is entirely intraperitoneal, suspended by the mesentery, allowing significant mobility. Grossly, the jejunum has thicker walls, a deeper red color due to greater vascularity, and more prominent plicae circulares—permanent transverse folds that enhance surface area—compared to the ileum. Histologically, it features tall villi and a moderate number of goblet cells, which increase in density distally. The forms the distal three-fifths of the (post-) and measures about 3 meters in length, occupying the lower right quadrant of the . Like the , it is intraperitoneal and mesentery-suspended but ends at the , where it joins the of the . It has a narrower lumen, thinner walls with more surrounding mesenteric fat, and fewer plicae circulares than the . A key distinguishing feature is the presence of Peyer's patches—aggregates of lymphoid tissue in the , particularly abundant along the antimesenteric border—which are sparse or absent in the and . Goblet cells are most numerous here, contributing to a higher mucus-secreting capacity. Transitions between regions are marked by changes in peritoneal attachments and histological characteristics rather than sharp anatomical boundaries. The shift from duodenum to jejunum occurs at the , where the retroperitoneal duodenum gives way to the mobile, mesentery-attached jejunum. The jejunum-to-ileum transition is gradual, characterized by decreasing prominence of plicae circulares, increasing mesenteric fat, and the appearance of Peyer's patches, along with a progressive rise in goblet cell density from proximal to distal segments.

Vascular supply

The arterial supply to the small intestine is primarily derived from the (), which originates from the at the level of the L1 vertebral body and supplies the structures from the distal to the proximal two-thirds of the . The proximal portion of the duodenum receives its blood supply from the celiac trunk via the gastroduodenal artery, which branches into the anterior and posterior superior pancreaticoduodenal arteries, forming an anastomotic arcade with the (a branch of the ) to supply the distal duodenum and pancreatic head. For the and , the gives rise to 12-15 jejunal and ileal branches that travel within the , forming 1-2 tiers of arterial arcades in the jejunum and 3-5 tiers in the ileum, from which straight terminal vessels known as vasa recta arise to directly perfuse the intestinal wall. These arcades, typically numbering 16-20 in total across both regions, provide a rich network of collateral circulation that enhances resilience to vascular occlusion. Venous drainage of the small intestine parallels the arterial supply, with veins accompanying the branches to form corresponding arcades and vasa recta that converge into the (). The collects blood from the entire small intestine, as well as the , , and parts of the and , before joining the to form the , which delivers nutrient-rich blood to the liver for processing. Portosystemic anastomoses exist in the , where pancreaticoduodenal veins connect portal tributaries to systemic veins draining the retroperitoneum, providing potential collateral pathways in cases of . The lymphatic drainage of the small intestine begins in the lacteals, specialized lymphatic capillaries located within the villi that absorb chylomicrons formed during fat digestion and transport them as . These lacteals converge into larger collecting vessels within the mesenteric lymph nodes, where lymph is filtered before ascending through the mesenteric to the and ultimately entering the to return to the systemic circulation. This system plays a critical role in absorption and immune surveillance by transporting dietary fats and antigens from the intestinal lumen. Key anastomoses in the small intestinal vasculature include the marginal artery of Drummond, an arterial collateral pathway formed by anastomoses between branches of the (such as the ileocolic and right colic arteries) and the (IMA), running along the mesenteric border of the colon but extending continuity to the terminal for protective collateral flow. This arcade ensures redundancy in blood supply, mitigating ischemia risk from occlusion of either the or IMA.

Histology

The wall of the small intestine consists of four principal layers: the mucosa, , muscularis externa, and (or in retroperitoneal portions). The mucosa, the innermost layer, is composed of a resting on a of and capped by a thin of . The epithelium features four main cell types: absorptive enterocytes, which dominate and facilitate uptake; mucus-secreting goblet cells, which protect the surface; peptide-producing Paneth cells, located at the base of crypts; and hormone-secreting enteroendocrine cells, which regulate and . The contains blood vessels, lymphatics, and scattered lymphoid elements, while the enables localized mucosal folding. The is a dense layer of rich in , blood vessels, lymphatics, and nerves, providing structural support and nutrient distribution. In the , it uniquely houses compound tubular , which secrete alkaline mucus to neutralize . The muscularis externa comprises an inner thick circular layer of for segmentation and an outer thinner longitudinal layer for propulsion, both under neural control. The outermost serosa, a thin visceral , covers most of the small intestine and consists of over , facilitating intraperitoneal mobility; retroperitoneal segments, such as parts of the , instead have an of fibrous tissue anchoring them. Specialized mucosal features enhance function: finger-like villi project into the lumen to maximize absorptive surface area, while tubular crypts of Lieberkühn invaginate into the for cell renewal and . Enterocytes on villi bear a of microvilli, embedded with such as (which hydrolyzes to glucose and ) and sucrase (which cleaves to glucose and fructose), completing breakdown at the apical . Paneth cells in crypt bases release and for innate immunity, and stem cells drive epithelial turnover every 3–5 days. Histological features vary regionally: the duodenum exhibits prominent Brunner's glands and shorter, broader villi; the jejunum has the tallest villi and deepest crypts for optimal absorption; and the ileum features aggregated Peyer's patches—lymphoid nodules spanning the lamina propria and submucosa—for immune surveillance, with progressively shorter villi distally. The enteric nervous system, intrinsic to the wall, coordinates these functions via two plexuses: the myenteric (Auerbach's) plexus between the muscularis externa layers, regulating peristalsis and motility; and the submucosal (Meissner's) plexus within the submucosa, controlling local secretion, blood flow, and epithelial transport. These networks operate semi-autonomously, integrating with extrinsic innervation.

Molecular biology

The molecular biology of the small intestine is characterized by distinct patterns of that underpin its epithelial specialization. Solute carrier (SLC) transporters, such as SLC5A1 encoding SGLT1, are highly expressed in enterocytes to mediate sodium-coupled glucose transport across the apical membrane. The CFTR gene (ABCC7) encodes a essential for anion secretion in the , with expression concentrated in cells. , including Hoxd12 and , establish regional identity along the anteroposterior axis, influencing compartment-specific morphogenesis and cellular differentiation in the gut tube. Protein expression in small intestinal enterocytes features markers that define their architecture and enzymatic roles. Villin (VIL1), an actin-binding protein, is a prominent cytoskeletal component of microvilli, while sucrase-isomaltase (SI) serves as a diagnostic marker for mature absorptive enterocytes. Expression gradients exist for certain proteins, with (ALPI) showing highest levels in the and progressively decreasing toward the , reflecting regional adaptations in luminal processing. Proteomic analyses via have cataloged extensive protein repertoires in small intestinal tissues, identifying over 5,000 proteins in crypt-enriched samples alone, highlighting the complexity of epithelial dynamics. Among these, proteins like play a in maintaining the intestinal barrier, forming seal-like structures between adjacent epithelial cells to regulate paracellular permeability. Post-2020 advances in single-cell RNA sequencing have elucidated niches within intestinal crypts, revealing transcriptional heterogeneity among Lgr5+ s and supporting stromal populations that orchestrate self-renewal and lineage commitment. These studies identify distinct clusters of mesenchymal and immune cells within the niche, providing molecular maps of crypt organization.

Embryological development

The small intestine arises from the segment of the primitive gut tube, which forms during the third week of embryonic development through , where endodermal cells invaginate to create the epithelial lining, surrounded by splanchnic that contributes to the muscular layers and connective tissues, while neural crest-derived cells form the . By the fourth week, the gut tube differentiates into , , and regions, with the midgut extending from the distal to the proximal two-thirds of the , including the future and . Rapid elongation and differential growth of the midgut during weeks 4 to 5 outpace the abdominal cavity's capacity, leading to physiological herniation of the intestinal loop into the extraembryonic via the around week 6. This herniated midgut loop, connected to the yolk sac by the vitelline duct, undergoes a complex counterclockwise rotation of 270 degrees around the axis of the () between weeks 5 and 10, consisting of an initial 90-degree turn during herniation followed by a 180-degree rotation as the loop returns to the by week 10. The return process repositions the posteriorly and the to the right lower quadrant, establishing the adult intestinal layout, while the vitelline duct typically obliterates. Concurrently, the intestinal lumen, initially occluded by proliferating al cells, undergoes recanalization through () and differential growth, restoring patency by the end of the first . Villus formation begins around weeks 9 to 12, driven by mesenchymal-epithelial interactions that increase absorptive surface area, with Sonic hedgehog (Shh) signaling from the endoderm playing a key role in patterning the gut tube and promoting villus morphogenesis. Disruptions in these processes can lead to congenital anomalies, such as , where the fails to return to the and remains covered by a peritoneal sac, occurring in approximately 1 in 5,000 live births. Malrotation results from incomplete or arrested rotation around the axis, leading to abnormal mesenteric fixation and a predisposition to , with an incidence of about 1 in 500 live births overall and symptomatic cases in roughly 1 in 6,000. Small bowel , characterized by intestinal discontinuity due to vascular accidents or failed recanalization, affects the or in approximately 1 in 5,000 newborns and represents a of neonatal obstruction.

Function

Secretion and digestion

The small intestine plays a central role in the digestion of nutrients through secretions from the , , and , as well as intrinsic intestinal enzymes. , released into the , contains to neutralize acidic from the and enzymes such as for carbohydrate breakdown, for fat digestion, and proteases (including , , and carboxypeptidases) for protein hydrolysis. These proteases are secreted as inactive zymogens and activated in the duodenal lumen by , an enzyme from the intestinal , which converts to ; active then activates the other zymogens. , produced by the and stored in the , is also delivered to the , where its salts emulsify dietary fats into micelles, facilitating access for pancreatic . salts undergo , with about 95% reabsorbed in the and returned to the via the for reuse, conserving this essential component of lipid digestion. The intestinal mucosa contributes directly to digestion via brush border enzymes anchored to the microvilli of enterocytes. These hydrolases complete the breakdown of oligosaccharides and peptides: for example, maltase catalyzes the hydrolysis of maltose into two glucose molecules via the reaction \text{maltose} + \text{H}_2\text{O} \rightarrow 2 \text{glucose}. Other key enzymes include sucrase-isomaltase for sucrose and isomaltose, lactase for lactose, and dipeptidases for small peptides, ensuring monomers are produced for subsequent processes. This enzymatic activity occurs optimally at a neutral to slightly alkaline pH of 6 to 7 in the duodenum, maintained by pancreatic bicarbonate secretion. Motility in the small intestine enhances digestion by mixing chyme with secretions and propelling it forward. , rhythmic local constrictions in the and , mix contents thoroughly without net movement, promoting enzyme-substrate contact. , coordinated waves of contraction and relaxation driven by the , advances chyme aborally at about 1 to 2 cm per second, ensuring progressive exposure to digestive agents. During , the (MMC)—a cyclical pattern of low-amplitude contractions sweeping from to ileum every 90 to 120 minutes—clears residual undigested material, preventing bacterial overgrowth. Hormonal signals from the duodenal mucosa fine-tune these processes. Cholecystokinin (CCK), released by I cells in response to fats and proteins, stimulates contraction for release and pancreatic enzyme secretion. , secreted by S cells when duodenal pH drops below 4.5 due to acidic , promotes pancreatic bicarbonate output to raise pH toward the optimal range for enzymatic activity. These hormones ensure synchronized secretion and maintain an environment conducive to efficient digestion.

Nutrient absorption

The small intestine is the primary site for the absorption of digested nutrients, water, and electrolytes from the intestinal lumen into the bloodstream or lymphatics via specialized transporters and diffusion mechanisms in the enterocytes. This process occurs across the apical and basolateral membranes of the epithelial cells, driven by electrochemical gradients and facilitated by sodium-dependent cotransport systems. Carbohydrate absorption primarily involves monosaccharides such as glucose and galactose, which enter enterocytes through the sodium-glucose linked transporter 1 (SGLT1) on the apical membrane via secondary active transport coupled with sodium ions. Fructose is absorbed independently via GLUT5. These monosaccharides then exit the basolateral membrane through the facilitated diffusion transporter GLUT2. Approximately 95% of ingested carbohydrates are efficiently absorbed in the small intestine. Protein absorption begins with luminal hydrolysis of peptides by digestive enzymes, followed by uptake of and small peptides into enterocytes. are transported across the apical via various sodium-dependent symporters, while di- and tripeptides are absorbed through the proton-coupled peptide transporter PEPT1. Inside the enterocytes, peptides undergo further to , which are then exported basolaterally via specific carriers. Over 95% of ingested proteins are absorbed, mainly as . Lipid absorption requires the formation of micelles in the , where salts solubilize monoglycerides and free fatty acids derived from dietary triglycerides. These diffuse across the apical into enterocytes, where they are re-esterified into triglycerides and packaged into chylomicrons within the and Golgi apparatus. Chylomicrons are then released into the via lacteals for systemic distribution, bypassing the . Vitamins and minerals are absorbed through specific carrier-mediated mechanisms tailored to their solubility and requirements. Fat-soluble vitamins (A, D, E, K) incorporate into micelles and follow the lipid absorption pathway into chylomicrons. Water-soluble vitamins, such as and , use dedicated transporters like the proton-coupled folate transporter (PCFT) or sodium-ascorbate cotransporters. Vitamin B12 binds to in the and is absorbed in the via involving the cubam complex. Minerals like iron and calcium employ dedicated apical transporters, such as DMT1 for iron, often regulated by body stores. Water and electrolyte absorption in the small intestine occurs primarily through osmotic gradients generated by active sodium uptake via the sodium-glucose cotransporter (SGLT1) and sodium-hydrogen exchangers (NHE3), with following passively through channels and paracellular pathways. Approximately 9 liters of are absorbed daily in the small intestine, accounting for ingested fluids and secretions from the , , and . Absorption exhibits regional specialization along the small intestine. The is the primary site for sugars, , and most water-soluble vitamins and minerals, benefiting from its proximal location and high transporter density. The specializes in the uptake of , bile salts via the apical sodium-dependent bile acid transporter (ASBT), and remaining electrolytes, ensuring efficient recycling of bile acids to support ongoing lipid digestion.

Immune functions

The small intestine plays a central role in mucosal immunity through the (GALT), which includes Peyer's patches primarily located in the and isolated lymphoid follicles distributed throughout the organ. These structures facilitate the sampling of luminal antigens by microfold (M) cells, specialized cells that transport antigens from the intestinal lumen to underlying immune cells, initiating both innate and adaptive responses. M cells, found in the follicle-associated epithelium overlying Peyer's patches, actively endocytose bacteria, viruses, and other particles, delivering them to antigen-presenting cells such as dendritic cells and macrophages within the subepithelial dome. A key component of adaptive mucosal immunity is secretory (SIgA), produced by plasma cells in the and transported across the via the polymeric immunoglobulin receptor. SIgA prevents adhesion to epithelial cells and neutralizes toxins without triggering , with human intestines secreting approximately 3 to 5 grams daily, representing the majority of production in the body. This dimeric coats commensal microbes and pathogens alike, promoting immune exclusion and maintaining barrier integrity. Innate defenses in the small intestine are bolstered by secreted by Paneth cells, located at the base of crypts, including α-defensins such as defensin-5 (HD5) and HD6, which disrupt microbial membranes and shape the composition. These peptides, stored in granules and released in response to microbial signals, contribute to host defense against pathogens while preserving beneficial commensals. Complementing this, goblet cells secrete a layer rich in mucins, forming a physical barrier that traps microbes and limits their access to the , thereby supporting innate immune homeostasis. Adaptive immune responses involve T-cell activation in the , where dendritic cells present antigens to CD4+ and CD8+ T cells, leading to effector functions against invaders. Regulatory T cells (Tregs), particularly + subsets, enforce tolerance to commensal antigens by suppressing excessive and promoting barrier maintenance through production like IL-10. This tolerance mechanism prevents while allowing controlled responses to threats. The small intestinal microbiome, with bacterial densities ranging from 10^3 to 10^8 cells per gram and increasing toward the , interacts dynamically with the to sustain . Commensal influence Treg differentiation and SIgA production, fostering , while —imbalances in microbial composition—has been linked to disrupted immune regulation in recent studies, highlighting the microbiome's role in preventing inflammatory conditions. For instance, 2020s research emphasizes how microbial metabolites modulate T-cell responses, underscoring the need for balanced microbiota-immune crosstalk.

Clinical significance

Disorders and diseases

The small intestine is susceptible to a variety of disorders and diseases that can impair its function, leading to symptoms such as malabsorption, diarrhea, and abdominal pain. Inflammatory conditions are among the most prevalent, including celiac disease and Crohn's disease, which involve immune-mediated damage to the intestinal mucosa. Celiac disease is an autoimmune disorder triggered by gluten ingestion in genetically predisposed individuals, resulting in villous atrophy and inflammation primarily in the proximal small intestine. It affects approximately 1% of the global population, with symptoms including chronic diarrhea, bloating, abdominal discomfort, and nutrient malabsorption leading to anemia and weight loss. Crohn's disease, a type of inflammatory bowel disease, causes transmural inflammation that commonly involves the terminal ileum, though it can affect any segment of the small intestine. Its exact cause is unknown but involves genetic, environmental, and immune factors; prevalence is estimated at 100-300 per 100,000 in Western populations. Recent trends show increasing prevalence of inflammatory bowel disease in newly industrialized and Asian countries, approaching Western levels (as of 2025). Symptoms often include abdominal pain, diarrhea, fatigue, and weight loss due to inflammation and potential strictures or fistulas. Infectious disorders of the small intestine frequently arise from bacterial or parasitic overgrowth, disrupting normal and . (SIBO) occurs when excessive colonize the small intestine, often due to disorders, structural abnormalities, or prior , leading to of undigested carbohydrates. Common symptoms include , , , and mal of fats and vitamins. Parasitic infections, such as giardiasis caused by lamblia, are transmitted via contaminated water or food and adhere to the small intestinal mucosa, impairing uptake. Symptoms typically manifest as watery , , cramps, and fatigue, particularly in acute cases. Neoplastic conditions in the small intestine are relatively rare but can significantly impact bowel function. Small bowel adenocarcinomas account for less than 2% of all gastrointestinal cancers and often arise in the or , associated with risk factors like celiac disease, , or genetic syndromes such as Lynch syndrome. They present with nonspecific symptoms including , obstruction, bleeding, and due to tumor growth. tumors, also known as neuroendocrine tumors, frequently originate in the and may secrete hormones like serotonin, leading to symptoms such as , , and flushing if metastatic (). These tumors are slow-growing but can cause local complications like . Vascular disorders, particularly mesenteric ischemia, compromise blood supply to the small intestine, resulting in tissue damage. Acute mesenteric ischemia often stems from (SMA) occlusion due to or , while chronic forms arise from gradual narrowing the vessels. Risk factors include advanced age, , , and hypercoagulable states. Symptoms of acute ischemia include severe, sudden out of proportion to physical findings, followed by bloody and ; chronic cases present with postprandial pain (), weight loss, and fear of eating. Recent epidemiological trends indicate a rising prevalence of (IBS), a affecting small intestinal and , potentially linked to post- gut alterations and persistent inflammation. Studies show IBS development in up to 12% of COVID-19 survivors, compared to lower rates in uninfected individuals, with symptoms including , , and altered bowel habits. Congenital anomalies, such as , may also manifest as small intestinal disorders but are primarily addressed in embryological contexts.

Diagnostic approaches

Diagnostic approaches to small intestine disorders involve a combination of non-invasive and invasive techniques aimed at visualizing the mucosa, assessing , evaluating , and measuring transit times. These methods are selected based on clinical presentation, such as obscure , chronic , or suspected inflammatory conditions like . A systematic evaluation often begins with tests and progresses to or if initial findings suggest small bowel involvement. Endoscopy provides direct visualization of the small intestine, which is crucial for detecting mucosal abnormalities. , a non-invasive method involving ingestion of a camera-in-a-pill, allows full assessment of the small bowel and is particularly effective for identifying ulcers, tumors, and sources of , with diagnostic yields ranging from 60% to 83%. It is recommended as the first-line investigation for obscure due to its ability to reach areas inaccessible to traditional . , a more advanced technique using balloons to advance the , enables deeper for biopsies and therapeutic interventions, achieving diagnostic yields up to 78% for lesions like tumors not fully characterized by . This method is especially useful for confirming diagnoses through histopathological examination. Imaging modalities complement endoscopy by providing structural details without direct mucosal access. Computed tomography (CT) enterography and magnetic resonance (MR) enterography involve oral contrast to distend the bowel, detecting , wall thickening, strictures, and extraluminal complications with yields of 40% to 64% for conditions like . CT enterography excels in showing mural hyperenhancement and stratification indicative of active . Small bowel follow-through (SBFT), using serial X-rays after contrast ingestion, outlines bowel contours but has lower sensitivity for subtle mucosal changes and is less favored as a primary tool compared to cross-sectional imaging. MR enterography is preferred in younger patients to avoid . Laboratory tests offer initial screening for small intestine dysfunction through non-invasive sampling. Serologic testing for anti-tissue (anti-tTG) IgA antibodies is highly sensitive (approximately 90%) for diagnosing celiac disease, a common small bowel disorder, and when markedly elevated (more than five times normal) combined with positive endomysial antibodies, it can obviate the need for . Fecal calprotectin, a marker of neutrophil-derived , correlates well with endoscopic findings in small bowel ; levels above 100 μg/g indicate significant with high diagnostic accuracy for mucosal involvement. The assesses small intestinal mucosal integrity by measuring urinary excretion after oral administration; normal excretion exceeds 4 g in 5 hours, while reduced levels suggest due to mucosal damage or bacterial overgrowth. Invasive procedures are reserved for cases requiring tissue sampling or functional assessment. , including device-assisted variants like double-balloon or single-balloon techniques, allows targeted biopsies and intervention for suspected or bleeding, with high diagnostic yields when capsule findings are inconclusive. Wireless motility capsules, ingested devices measuring pH, pressure, and transit times, evaluate small bowel motility disorders by quantifying transit duration, aiding diagnosis of conditions like chronic intestinal pseudo-obstruction. These capsules provide ambulatory data on regional transit, correlating with results. Recent advances in the 2020s have integrated () into to enhance detection accuracy. algorithms assist in identification of s and lesions in the small bowel, improving polyp detection rates and reducing reading times by automating anomaly flagging. These systems, using convolutional neural networks, achieve high sensitivity for small bowel pathologies, addressing limitations in manual review and enabling broader application in screening for obscure bleeding or early neoplasia.

Treatment and management

The primary medical treatment for celiac disease, an autoimmune disorder affecting the small intestine, is a strict lifelong that eliminates , , and to prevent villous and promote mucosal . For involving the small intestine, biologic therapies such as anti-tumor necrosis factor (anti-TNF) agents like are used to target inflammatory pathways, inducing and maintaining remission in moderate-to-severe cases. (SIBO) is typically managed with antibiotics, including , a non-absorbable broad-spectrum agent that reduces bacterial load and alleviates symptoms like and . Nutritional interventions play a key role in managing malabsorption syndromes. In short bowel syndrome following extensive resection, total parenteral nutrition (TPN) delivers calories, fluids, and electrolytes intravenously to support adaptation and prevent until intestinal function improves. Pancreatic enzyme replacement therapy is often prescribed for patients with small intestinal disorders causing , enhancing fat and nutrient digestion to mitigate and . Surgical approaches are reserved for complications such as obstruction or . Resection of the affected small bowel segment is standard for tumors or acute ischemia, with to restore continuity and prevent . In fibrostenotic , strictureplasty widens narrowed segments while preserving bowel length, reducing the risk of compared to repeated resections. For irreversible intestinal failure due to extensive loss, small bowel transplantation offers a curative option, though it remains rare with approximately 177 cases performed globally in 2023. Supportive measures complement primary therapies to optimize outcomes. , such as strains of and , aid in restoring the small intestinal disrupted by antibiotics or , potentially improving barrier function and reducing relapse risk in conditions like SIBO. Disease activity in small bowel Crohn's can be non-invasively monitored using fecal calprotectin levels, with elevations above 150 µg/g indicating ongoing and guiding adjustments to therapy. As of 2025, emerging strategies include fecal transplantation (FMT) for recurrent small intestinal infections, such as those caused by , which transfers healthy donor to reestablish diversity and prevent reinfection.

In other vertebrates

In mammals, the small intestine maintains a conserved structure consisting of the , , and , facilitating enzymatic and similar to that in humans, though its length and volume vary significantly with diet. Herbivores, such as , possess notably longer small intestines relative to body size compared to carnivores, enhancing the breakdown and of fibrous plant material through extended transit times and increased surface area. In ruminants like cows, the serves as the glandular "true " analogous to the , secreting acid and enzymes before digesta enters the small intestine for further processing and . Birds exhibit a shorter small intestine adapted for and efficient , complemented by the gizzard's mechanical grinding of food to reduce the digestive burden on the intestine. The is particularly prominent in avian species, where it receives and pancreatic secretions to initiate fat and protein breakdown, supporting the high metabolic demands of flight. Carnivorous birds tend to have even shorter and simpler small intestines than herbivorous ones, reflecting their protein-rich diets that require less . In fish, small intestine length varies markedly by trophic level, with carnivorous species featuring shorter tracts for quick processing of easily digestible prey, while herbivorous fish have elongated intestines to accommodate slower digestion of algae and plant matter. Certain primitive fish, such as sharks and rays, incorporate a spiral valve—a coiled internal structure that increases absorptive surface area and prolongs food retention without extending overall length. This adaptation maximizes nutrient extraction in environments where food may be sporadic. Reptiles and amphibians possess simpler small intestinal structures compared to endotherms. larvae often feature a typhlosole—a prominent longitudinal fold along the intestinal wall that boosts surface area for , while adult forms and reptiles typically have a straight or slightly coiled tube with mucosal folds rather than complex villi. These ectotherms exhibit physiological plasticity in their small intestines, rapidly upregulating production and transporter activity after infrequent meals to efficiently process large boluses during intermittent feeding bouts characteristic of their lifestyles. Across vertebrates, endothermic classes like mammals and demonstrate higher absorption efficiency in the small intestine than ectotherms, driven by elevated metabolic rates that necessitate rapid and complete uptake of glucose and other to sustain and activity.

Evolutionary aspects

The small intestine originated from the endodermal layer of the primitive gut tube in early chordates, dating back approximately 500 million years ago during the period. In these ancestral forms, the digestive tract was a simple epithelial-lined lumen primarily reliant on through phagocytic cells, lacking specialized absorptive structures. This basic configuration persisted in early vertebrates, such as agnathans, where the gut functioned as a straightforward conduit for processing without regional differentiation. A pivotal evolutionary occurred in gnathostomes, the vertebrates that emerged around 420 million years ago, with the development of intestinal villi to enhance and absorption. These finger-like projections dramatically increased the gut's surface area, allowing for more efficient uptake from a diverse , including complex prey. Fossil evidence from Devonian-aged fish, such as preserved gastrointestinal impressions in placoderms and chondrichthyans, reveals early spiral valve structures that prefigured modern adaptations, indicating a gradual refinement of intestinal morphology during the Silurian-Devonian transition. estimates further support this timeline, placing the divergence of key absorptive enzymes, such as those involved in carbohydrate and protein breakdown, around 400 million years ago in association with gnathostome radiation. In tetrapods, which transitioned to terrestrial environments approximately 360 million years ago, the small intestine adapted through and expanded surface area to process drier, often plant-based diets requiring prolonged retention and breakdown. These changes were facilitated by whole-genome duplication events in early vertebrates, which diversified gene families encoding nutrient transporters, such as and SLC proteins, enabling specialized uptake mechanisms. Dietary pressures profoundly shaped these traits: carnivores typically exhibit shorter small intestines relative to body length (e.g., about 3 times in felids like , suited to rapid of protein-rich meals), whereas herbivores display greater relative (e.g., about 6-9 times in , accommodating fibrous vegetation). Recent comparative genomic studies from the 2020s highlight the conservation of clusters in patterning the intestine's anterior-posterior axis across vertebrates, ensuring regional functional specialization from to despite phylogenetic divergence.

History and culture

Historical perspectives

The understanding of the small intestine's structure and function evolved gradually through ancient observations, dissections, and modern physiological experiments, marked by both breakthroughs and initial misconceptions. In the 3rd century BCE, the Greek anatomist Herophilus provided one of the earliest known descriptions of the , the proximal segment of the small intestine, based on human dissections in . By the 2nd century CE, the physician built on earlier ideas but introduced erroneous concepts of , positing that ingested food was transformed in the into —a nutrient-rich, milky substance—before absorption through the small intestine's walls into the , a view that persisted for centuries despite its inaccuracies regarding enzymatic processes. The marked a shift toward empirical , with Andreas Vesalius's 1543 publication of De humani corporis fabrica offering precise illustrations and textual accounts of the small intestine's gross structure, including its divisions into , , and , thereby correcting Galenic distortions through direct cadaveric study. In the mid-17th century, Marcello Malpighi advanced this knowledge by employing early compound microscopes to observe and describe the intestinal villi for the first time, identifying these finger-like projections as key to the organ's absorptive capacity. Nineteenth-century physiology deepened insights into digestive coordination, as demonstrated in 1848 that pancreatic secretions play a critical role in fat emulsification within the small intestine, revealing the organ's dependence on accessory glands for complete nutrient breakdown. This era culminated in 1902 when William Bayliss and identified , the first discovered, released from duodenal cells in response to acidic contents and signaling the to secrete , a finding that established hormonal regulation of small intestinal function and birthed as a . Twentieth-century research elucidated molecular absorption mechanisms, with Robert K. Crane's 1960 proposal of the sodium-glucose linked transporter (SGLT1) explaining active glucose uptake across the small intestinal epithelium, a model that transformed views on secondary active transport. Concurrently, in the 1950s, clinical studies linked celiac disease to gluten ingestion, showing how wheat proteins trigger villous atrophy and malabsorption in the small intestine of genetically predisposed individuals, paving the way for gluten-free dietary management. A pivotal clinical advancement came in the 1990s, when the first successful small bowel transplants were achieved, notably through multivisceral procedures at the , offering life-sustaining options for patients previously reliant on .

In society and media

The small intestine has gained prominence in contemporary culinary trends centered on "gut health," particularly through the promotion of -rich foods that aim to support microbial balance in the digestive tract. Since the 2010s, the popularity of fermented products like , , and has surged, driven by consumer interest in enhancing nutrient absorption and overall digestion via the gut microbiome. This movement reflects broader lifestyle advice in popular , where are touted for modulating gut flora to improve intestinal function, though experts emphasize that diverse fiber intake remains more effective than supplements alone. Historically, rituals across cultures have targeted digestive processes, including those in the small intestine, by allowing periods of rest for nutrient absorption and microbial recovery; ancient practices, such as those in Egyptian purification rites or Greek healing traditions, viewed intermittent abstinence as a means to reset gut health. In media portrayals, the small intestine often appears in medical dramas through scenes of surgical interventions, highlighting its vulnerability in abdominal emergencies and the complexities of procedures like resections or transplants. Shows like frequently depict gastrointestinal surgeries involving the small bowel, contributing to public awareness of digestive disorders while sometimes prioritizing dramatic tension over anatomical precision, as noted in analyses of television's influence on viewers' surgical perceptions. has amplified informal representations via memes about (IBS), which affects small intestine and , with viral content humorously capturing symptoms like and urgency to destigmatize the condition; campaigns like BelliWelli's 2021 billboards declaring "Hot girls have IBS" extended this trend online, fostering community discussions on gut-related challenges. Educational curricula in emphasize the small intestine's role in nutrient , portraying it as a key site where villi and microvilli facilitate the uptake of sugars, , and fats into the bloodstream, a central to high school lessons on human physiology. initiatives in the have further spotlighted small intestine-related issues, such as celiac disease, which damages its lining and impairs ; annual awareness campaigns, including the Celiac Disease Foundation's "Shine a Light" efforts since 2020, have illuminated landmarks worldwide in May to educate on and management, securing proclamations in 27 U.S. states and the District of Columbia in 2025. Symbolically, the small intestine serves as a for intricate "" in , evoking themes of and , as seen in poetic explorations of emotional or in 19th-century works by and Whitman that liken intellectual absorption to intestinal . Ethical debates surrounding small intestine transplants raise concerns about donor , resource , and quality-of-life outcomes, particularly in pediatric cases where the procedure's high risks—such as rejection and —must be weighed against benefits for patients. In 2025, social media continues to shape perceptions of gut microbiome diets, with platforms like promoting viral regimens high in prebiotics and fermented foods to optimize small intestine flora, though critiques highlight misinformation in these trends over evidence-based nutrition.

References

  1. [1]
    Physiology, Small Bowel - StatPearls - NCBI Bookshelf
    Jan 31, 2024 · The primary function of the small intestine is to break down food, absorb nutrients, extract water, and move food along the GI tract. The ...
  2. [2]
    Anatomy, Abdomen and Pelvis, Small Intestine - StatPearls - NCBI
    Feb 18, 2025 · The small intestine is a crucial gastrointestinal segment involved in nutrient digestion and absorption, various endocrine functions, and immune protection.
  3. [3]
    The Small Intestine: Normal Structure and Function - SpringerLink
    The small bowel in post mortem studies is 600 cm in length but is significantly shorter in life (Hirsch et al., 1956)1. The surface area for absorption is ...The Small Intestine: Normal... · Chapter Pdf · Author Information<|separator|>
  4. [4]
    In Vivo Small Bowel Length is Longer than in Formalin-Fixed ...
    This study indicated that when SBL was measured in the same consistent manner, the small bowel was shorter in formalin-fixed cadavers compared to living ...
  5. [5]
    Anatomy of the Small Intestine - SEER Training Modules
    The small intestine is a tube measuring about 2.5 cm in diameter. The complete small intestine is approximately 600 cm (20 feet) long and coiled in loops.
  6. [6]
    Normal small bowel wall characteristics on MR enterography
    We found the mean diameter of the duodenum to be 24.8 mm (S.D. = 4.5 mm), jejunum to be 24.5 mm (S.D. = 4.2 mm), proximal ileum to be 19.5 mm (S.D. = 3.6 mm) ...Normal Small Bowel Wall... · Abstract · Introduction
  7. [7]
    Anatomical study of the length of the human intestine
    This anatomical study aimed to assess the length of the different intestinal segments, their variation and their correlation with sex, age, weight and height.
  8. [8]
    Using Anthropometric and Demographic Factors to Predict Small ...
    The present study shows that height, male gender, age, and length of the right hemithorax have direct relationships to the small intestinal length, while the 2 ...
  9. [9]
    A comprehensive review of small bowel length measurement
    The key factors influencing measurement variability are discussed, including methodological differences related to the measurement tool (e.g. intraoperative vs.
  10. [10]
    The Small and Large Intestines | Anatomy and Physiology II
    From proximal (at the stomach) to distal, these are the duodenum, jejunum, and ileum. The shortest region is the 25.4-cm (10-in) duodenum, which begins at the ...The Small Intestine · The Large Intestine · Glossary
  11. [11]
    Surface area of the digestive tract – revisited - Taylor & Francis Online
    Surface amplification due to microvilli in the colon is ∼6.5 times. The mean total mucosal surface of the digestive tract interior averages ∼32 m2, of which ...
  12. [12]
    Physiology and function of the small intestine - Wiley Online Library
    The average length of the small intestine is 6.9 m but structural adapta- tions including mucosal folds, villi and microvilli mean that its surface area is 200– ...
  13. [13]
    Small Intestine - Histology at SIU - Southern Illinois University
    May 14, 2022 · The duodenum is readily distinguished from other regions of the small intestine by the presence of submucosal Brunner's glands, which may pack ...
  14. [14]
    Anatomy, Abdomen and Pelvis: Superior Mesenteric Artery - NCBI
    The ileocolic artery is the inferior most branch of the superior mesenteric artery and supplies the ascending colon, appendix, cecum, and ileum.Bookshelf · Anatomy, Abdomen And Pelvis... · Blood Supply And Lymphatics
  15. [15]
    Blood supply and innervation of the small intestine - Kenhub
    The duodenum is supplied by gastroduodenal and pancreaticoduodenal arteries, while jejunum and ileum are supplied by superior mesenteric artery. Both have ...
  16. [16]
    Jejunal and ileal branches of the superior mesenteric artery
    Aug 5, 2024 · From the arcades, straight arteries (also known as the vasa recta) pass to the small bowel. The arcade numbers in jejunum is lesser than the ...
  17. [17]
    An investigation of human jejunal and ileal arteries
    Jun 3, 2009 · The number of tiers of arcades varies between the jejunum, where there are typically one or two, and the ileum, where there are often three to ...
  18. [18]
    Anatomy, Abdomen and Pelvis: Superior Mesenteric Vein - NCBI - NIH
    The superior mesenteric vein receives many tributaries to drain the various organs of the gastrointestinal system. ... the small intestine through various venous ...
  19. [19]
    Superior Mesenteric Vein: Anatomy, Location & Function
    Aug 3, 2023 · This is a network of veins that drains blood from organs in your belly and sends it to your liver. Your SMV is one of the most important veins ...
  20. [20]
    A Comprehensive Review of Portosystemic Collaterals in Cirrhosis
    Portosystemic collateral formation in cirrhosis plays an important part in events that define the natural history in affected patients.
  21. [21]
    The Intestinal Lymphatic System: Functions and Metabolic Implications
    Once inside the lacteals, CMs are transported via the lymph through mesenteric lymph nodes and collecting lymphatic vessels, ultimately reaching the ...
  22. [22]
    Lymphatics of abdomen and pelvis: Anatomy and drainage - Kenhub
    Lymph from the lacteal passes sequentially through these group of lymph nodes before finally ending up in the superior mesenteric lymph nodes. Lymph from the ...
  23. [23]
    Microanatomy of the intestinal lymphatic system - PMC
    The intestinal lymphatic system is comprised of two non-communicating lymphatic networks; one containing the lacteals draining the villi and the connecting ...
  24. [24]
    Marginal artery of Drummond: Anatomy, branches, supply - Kenhub
    The marginal artery of Drummond is an anastomosis formed by branches of the superior and inferior mesenteric arteries. Master its anatomy now at Kenhub!
  25. [25]
    Marginal artery of Drummond | Radiology Reference Article
    May 20, 2020 · The junction of the SMA and IMA territories is at the splenic flexure. Anastomoses here are often weak or absent, hence the marginal artery ...
  26. [26]
    Intestinal Goblet Cells and Mucins in Health and Disease
    The intestinal mucosal epithelium consists of four main cell types—absorptive enterocytes, goblet cells, Paneth cells, and enteroendocrine cells—which undergo ...
  27. [27]
    Intestinal Architecture and Development - NCBI - NIH
    The primary functions of GI tract include digestion and absorption of nutrients, secretions, and immunoresponse. The unique architecture of the GI tract ...
  28. [28]
    Brunner's glands: a structural, histochemical and pathological profile
    Brunner's glands are unique to mammals, located in the proximal duodenum, and produce mucus that lubricates the intestinal tract.
  29. [29]
    Intestinal mucosal atrophy and adaptation - PMC - PubMed Central
    The microvilli are covered by a glycocalyx coat that acts as a physical barrier and contains brush border enzymes. Enterocytes are joined by tight junctions to ...
  30. [30]
    Intestinal development and differentiation - PMC - PubMed Central
    One type of absorptive cell (enterocyte) and four types of secretory cells (goblet, Paneth, enteroendocrine and tuft cells) comprise the small intestinal ...
  31. [31]
    Enteric Nervous System in the Small Intestine - PubMed Central - NIH
    The principal components of the ENS are the myenteric (Auerbach) and the submucosal (Meissner) plexuses. The myenteric plexus, located between the longitudinal ...
  32. [32]
    Physiology, Gastrointestinal Nervous Control - StatPearls - NCBI - NIH
    The enteric nervous system includes the myenteric plexus, which exhibits control over the longitudinal and circular muscle layers. Additionally, it is ...
  33. [33]
    Na+-d-glucose Cotransporter SGLT1 is Pivotal for Intestinal ... - NIH
    These data provide evidence that SGLT1 is required for small intestinal mass absorption of d-glucose. To determine whether d-glucose transport across the BBM ...
  34. [34]
    CFTR pharmacology and its role in intestinal fluid secretion
    CFTR is expressed at the apical membrane of enterocytes in intestine, and is thought to be the primary pathway for Cl− and hence fluid secretion into the ...
  35. [35]
    Establishment of Intestinal Identity and Epithelial-Mesenchymal ...
    Mutations in a number of Hox genes result in malformations in certain gut regions, but do not cause whole-sale AP transformation of the gut (Aubin et al., 1997; ...
  36. [36]
    Development of a primary human Small Intestine-on-a-Chip using ...
    Feb 13, 2018 · Genes analyzed include sucrose-isomaltase (SI) and alkaline phosphatase (ALPI) that are specific for absorptive enterocytes; mucin 2 (MUC2) ...
  37. [37]
    Mutually Distinctive Gradients of Three Types of Intestinal Alkaline ...
    Sep 1, 2004 · Background/Aims: A descending gradient of alkaline phosphatase (AP) activity is well known to exist in the rat intestine.
  38. [38]
    Region-Specific Proteome Changes of the Intestinal Epithelium ...
    Apr 28, 2020 · All crypt samples were analyzed by DIA mass spectrometry. We identified in total 5,762 proteins, of which 3,668 were quantified across all ...
  39. [39]
    Proteomic and bioinformatic analysis of epithelial tight junction ...
    Zonula occludens, also known as the tight junction, is a specialized cell-cell interaction characterized by membrane "kisses" between epithelial cells.
  40. [40]
    Organization of the human intestine at single-cell resolution | Nature
    Jul 19, 2023 · Previous studies have mapped cell types using single-cell RNA-sequencing (scRNA-seq) and have catalogued cell types across the intestine.
  41. [41]
    Single-cell RNA sequencing of intestinal crypts reveals vital events ...
    Oct 25, 2023 · In this study, we executed single-cell RNA sequencing of intestinal crypts. We analyzed the differentially expressed genes (DEGs) at ...
  42. [42]
    Embryology, Bowel - StatPearls - NCBI Bookshelf
    The small and large intestines undergo rapid growth during weeks four and five of development. Embryological science believes that the enlarging intestines ...Introduction · Development · Cellular · Testing
  43. [43]
    Embryology, Gastrointestinal - StatPearls - NCBI Bookshelf - NIH
    During the third week of development, gastrulation occurs; the epiblast cells invaginate, replace the hypoblast, and proliferate into the middle layer, while ...Introduction · Development · Cellular · Pathophysiology
  44. [44]
    Ontogeny, growth and development of the small intestine - NIH
    Development of the small intestine is comprised of three stages: (1) morphogenesis and cell proliferation, (2) cell differentiation, and (3) functional ...
  45. [45]
    Embryology, Midgut - StatPearls - NCBI Bookshelf - NIH
    Following gastrulation, primitive gut tube development begins as a hollow chamber of endoderm is then surrounded by mesodermal cells. The endodermal cells ...Introduction · Development · Cellular · Mechanism
  46. [46]
    Small Intestinal Atresia and Stenosis - Medscape Reference
    Sep 28, 2023 · Colonic atresia develops in 1 in 20,000-66,000 births and occurs in fewer than 15% of babies with intestinal atresia. The bowel becomes ...Practice Essentials · Pathophysiology · Etiology · Epidemiology
  47. [47]
    Intestinal Malrotation & Volvulus | Symptoms, Diagnosis & Treatment
    Incidence. Intestinal malrotation occurs in one of every 500 live births in the United States. Up to 40% of patients with malrotation show signs of the disease ...
  48. [48]
    https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4956471/
  49. [49]
    Physiology, Digestion - StatPearls - NCBI Bookshelf
    Sep 12, 2022 · Digestion is the process of mechanically and enzymatically breaking down food into substances for absorption into the bloodstream.
  50. [50]
    SI activity and function – Vet Med: Applied GI Physiology
    The small intestine does most of the work. It is responsible for the majority of fluid absorption as well as for nutrient digestion and absorption.
  51. [51]
    Physiology, Nutrient Absorption - StatPearls - NCBI Bookshelf
    Oct 28, 2023 · From the mouth to the anus, its length is approximately 9 meters (30 feet). The gastrointestinal tract's wide range of functions include the
  52. [52]
    Small Intestine | MUSC Health | Charleston SC
    The absorptive function is so efficient that in a normal adult with a normal diet, over 95% of ingested carbohydrates and proteins are absorbed. Specific ...
  53. [53]
    Small Intestine - Digestion - Absorption - TeachMePhysiology
    May 1, 2023 · There are three carbohydrate products which are absorbed by the small intestine; glucose, galactose and fructose. Digestion of starch is ...<|control11|><|separator|>
  54. [54]
    Peyer Patches - StatPearls - NCBI Bookshelf - NIH
    Jan 2, 2023 · Peyer patches are a group of well-organized lymphoid follicles located in the lamina propria and submucosa of the distal portion of the small intestine.Definition/Introduction · Issues of Concern · Clinical Significance
  55. [55]
    The Roles of Peyer's Patches and Microfold Cells in the Gut Immune ...
    Oct 9, 2019 · Microfold (M) cells are located in the epithelium covering mucosa-associated lymphoid tissues, such as the Peyer's patches (PPs) of the small ...
  56. [56]
    Histology, M Cell - StatPearls - NCBI Bookshelf
    M cells (or microfold cells, a name given due to their unique structure) are specialized intestinal epithelial cells that are primarily found overlying gut- ...Introduction · Structure · Function · Histochemistry and...
  57. [57]
    Re-thinking the functions of IgA+ plasma cells - PMC - PubMed Central
    Approximately 80% of all human PC are located in organized gut-associated lymphoid tissues (GALT) where they produce more IgA (∼50 mg/kg/day) than all other Ig ...
  58. [58]
    IgA and Mucosal Homeostasis - Madame Curie Bioscience Database
    Production and transport of S-IgA represent a major physiological investment. In humans, the intestine alone receives 3 to 5 g of S-IgA each day, testifying to ...
  59. [59]
    IgA and the intestinal microbiota: the importance of being specific
    Nov 18, 2019 · IgA is the most abundantly produced antibody in mouse and human. Most IgA-secreting plasma cells are localized in mucosal tissues, foremost the ...Missing: output | Show results with:output
  60. [60]
    Paneth cells of the human small intestine express an antimicrobial ...
    This gene, designated human defensin-5, is highly expressed in Paneth cells of the small intestine. This is the first example of an antimicrobial peptide gene ...
  61. [61]
    Paneth cell α-defensins HD-5 and HD-6 display differential ... - PNAS
    Feb 11, 2019 · Paneth cells provide intestinal host defense against pathogens and control the healthy microbiota by secreting antimicrobial peptides.
  62. [62]
    goblet cells and the intestinal mucus layer - PubMed
    Available data indicate that intestinal microbes may affect goblet cell dynamics and the mucus layer directly via the local release of bioactive factors.
  63. [63]
    Regulatory T Cells and Immune Tolerance in the Intestine - PMC
    Regulatory T cells are critical for continued immune tolerance in the intestine through active control of innate and adaptive immune responses.
  64. [64]
    Revised Estimates for the Number of Human and Bacteria Cells in ...
    Aug 19, 2016 · The concentration of bacteria in the stomach and the upper 2/3 of the small intestine (duodenum and jejunum) is only 103–104 bacteria/mL, owing ...Missing: cm2 | Show results with:cm2
  65. [65]
    The emerging role of the small intestinal microbiota in human health ...
    Apr 19, 2023 · The microbial density in the SI microbiota is estimated at 103 - 108 cells/g, with an increasing gradient going from a low density in the ...Missing: 2020s | Show results with:2020s
  66. [66]
    https://journals.physiology.org/doi/abs/10.1152/physrev.00020.2023
  67. [67]
    Optimal Diagnostic Approaches for Patients with Suspected Small ...
    Jun 22, 2016 · In this article, we review the systematic approach for patients with suspected small bowel disease based on these advanced endoscopic and imaging systems.
  68. [68]
    Approach to the Patient with Diarrhea and Malabsorption - PMC
    ... the anti-tTG IgA and EMA antibodies are virtually diagnostic of celiac disease. ... Among individuals with AIDS and diarrhea, results of fecal fat and d-xylose ...
  69. [69]
    Fecal Calprotectin for Small Bowel Crohn's Disease: Is It a Cutoff ...
    Sep 15, 2022 · Calprotectin is a calcium-binding protein with antimicrobial, antiproliferative, and proinflammatory properties. Its concentration in the feces ...
  70. [70]
    Impact of enteroscopy on diagnosis and management of small ...
    Capsule endoscopy (CE) and device-assisted enteroscopy (DAE) allow the clinician to assess the entire small bowel in the search for suspicious lesions, or a ...
  71. [71]
    A Technical Review and Clinical Assessment of the Wireless Motility ...
    The WMC is a single-use, orally ingested, nondigestible capsule that is capable of measuring gastric emptying time (GET), small bowel transit time (SBTT), ...
  72. [72]
    From Data to Insights: How Is AI Revolutionizing Small-Bowel ... - NIH
    Jan 29, 2024 · This review provides an overview of the current state-of-the-art of AI in the scope of small-bowel study, with a particular focus on capsule ...
  73. [73]
    Eating, Diet, & Nutrition for Celiac Disease - NIDDK
    If you have celiac disease, you will need to remove foods and drinks that contain gluten from your diet. Following a gluten-free diet can relieve celiac disease ...How will I need to change my... · How can I identify and avoid...
  74. [74]
    Crohn's disease - Diagnosis and treatment - Mayo Clinic
    Oct 29, 2024 · Biologics. This class of therapies targets proteins made by the immune system. Types of biologics used to treat Crohn's disease include: ...
  75. [75]
    Small intestinal bacterial overgrowth (SIBO) - Diagnosis & treatment
    Small intestinal bacterial overgrowth (SIBO) can occur when excess bacteria builds up in the small intestine. Learn more about this bowel disorder.Treatment · Preparing For Your... · What To Expect From Your...
  76. [76]
    Short-Bowel Syndrome - Medscape Reference
    Aug 27, 2024 · Patients with SBS are now routinely treated with total parenteral nutrition (TPN), especially early in their course. Despite bowel adaptation ...<|separator|>
  77. [77]
    Exploring the role of pancreatic enzyme replacement therapy in ...
    Pancreatic enzyme replacement therapy (PERT) has been proposed as a treatment for patients with short bowel syndrome (SBS) to address fat malabsorption and ...
  78. [78]
    Small Bowel Resection - StatPearls - NCBI Bookshelf
    Resections are planned based on the intended anastomosis: stapled or hand sewn. For a stapled anastomosis, defects are made through the mesentery close to the ...
  79. [79]
    Successful management of adhesion related small bowel ischemia ...
    Sep 10, 2019 · The standard procedure for this condition involves resection of the ischemic bowel and primary anastomosis[31].
  80. [80]
    Strictureplasty | Crohn's & Colitis Foundation
    A strictureplasty is a surgical procedure to repair a stricture by widening the narrowed area without removing any portion of your intestine.
  81. [81]
    [PDF] 2023-data-global-report-20022025.pdf
    Dec 31, 2024 · *Additionally, small bowel transplants from DCD were reported by Spain (n=1). Page 20. DONATION & TRANSPLANTATION GLOBAL REPORT 2023. *Number ...
  82. [82]
    Probiotics, Nutrition, and the Small Intestine - PubMed
    Jan 13, 2020 · Probiotics are promising remedial treatments for symptoms of small intestine (SI) diseases and promoters of overall good health.
  83. [83]
    Fecal microbiota transplantation: Current evidence and future ...
    Jul 1, 2025 · Fecal microbiota transplantation (FMT), a well-established procedure, is recognized for effectively treating recurrent Clostridioides difficile infection.Missing: small | Show results with:small
  84. [84]
    Comparative Digestive Physiology - PMC - PubMed Central
    Across species, herbivores tend to have more voluminous mass-corrected digestive tracts than carnivores in fish (136, 379, 458), mammals, birds, reptiles, and ...
  85. [85]
    Mammalian intestinal allometry, phylogeny, trophic level and climate
    Therefore, it has been widely claimed that herbivores' intestines are longer than those of carnivores [2,3,5–8]. Typically, this claim has been supported by ...
  86. [86]
    Understanding the Ruminant Animal Digestive System
    The small and large intestines follow the abomasum as further sites of nutrient absorption. The small intestine is a tube up to 150 feet long with a 20-gallon ...Ruminant Digestive Anatomy... · Ruminant Digestive... · Carbohydrate Digestion
  87. [87]
    Digestive Anatomy and Physiology of Birds
    Birds use beaks and gizzards for food processing, have a glandular stomach and gizzard, a small intestine similar to mammals, and a large intestine with a  ...
  88. [88]
    Morphometrics of the Avian Small Intestine Compared with That of ...
    Within mammals, the small intestine nominal surface area, volume, and mass of carnivores and herbivores were slightly larger than those of omnivores.
  89. [89]
    Digestion - Fernbank Science Center
    The small intestine varies in length and structure depending on the diet of the species. Carnivorous birds tend to have shorter, less complex small intestines.
  90. [90]
    Diet and habitat as determinants of intestine length in fishes - PMC
    Apr 12, 2024 · Herbivores had significantly relatively stouter bodies and longer intestines than omni- and faunivores. Among faunivores, corallivores had ...
  91. [91]
    Ontogenetic development of intestinal length and relationships to ...
    Feb 25, 2013 · Numerous studies have shown that digestive tracts across all vertebrate classes tend to be shortest in carnivores, intermediate in omnivores and ...
  92. [92]
    Expression and Function of ABC Proteins in Fish Intestine - PMC
    ... spiral valve, which increases the absorption surface area and delays the food passage. In addition, mucosal folds increase the surface area of the spiral ...
  93. [93]
    Microbiota and Mucosal Immunity in Amphibians - PubMed Central
    This epithelium is organized in a simple tubular structure, with a central fold called the typhlosole. Upon metamorphosis, the tadpole's intestine changes into ...
  94. [94]
    Answers-2, BIO 3220, Digestive System - MSU Denver Sites (2020)
    The purpose of typhlosole, coil, ceca, and villi is to increase surface area for more efficiency in digestion. 17. List the three pars of a tetrapod small ...
  95. [95]
    (PDF) Ott BD, Secor SM.. Adaptive regulation of digestive ...
    Aug 6, 2025 · The adaptive interplay between feeding habits and digestive physiology is demonstrated by the Burmese python, which in response to feeding ...Missing: intermittent | Show results with:intermittent
  96. [96]
    [PDF] Metabolic rate and environmental productivity: Well-provisioned ...
    8-fold difference between endotherms (''warm- blooded'' birds and mammals) and ectotherms (''cold-blooded'' reptiles, amphibia, and fish) (2), and also the ca.
  97. [97]
    Structure, Development and Evolution of the Digestive System - NIH
    The digestive system is formed by specialized cells and organs, with a conserved gut pattern and diverse architectures, and uses both extracellular and ...
  98. [98]
    Exceptional preservation reveals gastrointestinal anatomy and ...
    Jan 6, 2016 · Most paleontological perspectives on the vertebrate GIT are based on indirect evidence from fossilized faeces (coprolites)11 because the ...
  99. [99]
    A molecular timescale for vertebrate evolution - PubMed
    Here we present divergence-time estimates for mammalian orders and major lineages of vertebrates, from an analysis of 658 nuclear genes.
  100. [100]
    Structural Flexibility of the Digestive System of Tetrapods — Patterns ...
    Longer digestive tracts in herbivorous vertebrates are thought to increase the amount of food that can be ingested per feeding bout and lead to longer retention ...
  101. [101]
    Clear Evidence for Two Rounds of Vertebrate Genome Duplication
    The evolutionary patterns of gene duplications were reconstructed by comparing the complete gene sets of a tunicate (sea squirt), fish, mouse, and human. The 4- ...
  102. [102]
    Ontogenetic development of intestinal length and relationships to ...
    Feb 25, 2013 · Numerous studies have shown that digestive tracts across all vertebrate classes tend to be shortest in carnivores, intermediate in omnivores and ...
  103. [103]
    Comparative genomics of Hox and ParaHox genes among major ...
    Jan 23, 2023 · Hox and ParaHox genes (HPHGs) are key developmental genes that pattern regional identity along the anterior–posterior body axis of most animals.
  104. [104]
    Greek anatomist herophilus: the father of anatomy - PMC - NIH
    Herophilus described the salivary glands and named the first part of the small intestine, duodenum (von Staden 1989). He made the first accurate description of ...
  105. [105]
    History of the Stomach and Intestines
    Galen saw the stomach as an animate being that could feel its own emptiness and generate the sensation of hunger, writing: "[Nature] has granted to the stomach ...
  106. [106]
    a translation of De humani corporis fabrica libri septem. Book V, The ...
    The organs of nutrition -- The peritoneum -- The gullet and stomach -- The omentum -- The intestines -- The mesentery -- The liver -- The bladder for yellow ...
  107. [107]
    Marcello Malpighi (1628-1694): Pioneer of microscopic anatomy ...
    Sep 22, 2018 · Malpighi was one of the first to use the compound microscope (an instrument designed by Galileo in 1609) and made the most important discovery ...
  108. [108]
    The experimental counter-proof in the office of Claude Bernard
    In 1848 Claude Bernard discovered that pancreatic secretion could emulsify and saponify fatty substances. This article, based on his original manuscripts, shows ...
  109. [109]
    Secretin and the exposition of hormonal control - PMC - NIH
    Bayliss and Starling first communicated their discovery to the Royal Society only one week after the experiment (Bayliss & Starling, 1902a) and published the ...
  110. [110]
    Robert K. Crane—Na+-glucose cotransporter to cure? - PMC - NIH
    Mar 22, 2013 · “On August 24, 1960 in a lecture presented at Prague during a Symposium on Membrane Transport and Metabolism I proposed for the first time ...
  111. [111]
    Celiac Disease: A Disorder Emerging from Antiquity, Its Evolving ...
    The gluten-free diet has been recommended for treatment of celiac disease for more than a half-century, as a result of the seminal early clinical studies by ...
  112. [112]
    History of Intestinal Transplantation - Children's Hospital of Pittsburgh
    In Ontario, Canada, Dr. Grant performs the first successful liver-intestinal transplant. 1992. Microchimerism [the coexistence of donor and recipient cells] is ...
  113. [113]
    Probiotics for human health –new innovations and emerging trends
    Nov 26, 2012 · The role of the gut microbiome in human health and disease with a particular emphasis on therapeutic use of probiotics under specific medical ...
  114. [114]
    'Gut health' and the microbiome in the popular press - BMJ Open
    Lifestyle choices including nutrition, taking probiotics, stress management and exercise are often promoted as means of reaping the microbiome-related health ...
  115. [115]
    A Global History of Intermittent Fasting: From Ancient Rituals to ...
    Oct 14, 2025 · Ancient Egyptians practiced fasting for purification and healing, with priests observing fasting periods before important rituals. Egyptian ...Fasting In World Religions · Ancient Medicine · Intermittent Fasting In The...
  116. [116]
    Impact of Medical TV Shows on the Surgical Knowledge of Non ...
    Oct 21, 2022 · This study assesses the impact medical TV shows can have on the surgical knowledge of non-healthcare students and the difference in knowledge between different ...
  117. [117]
    From social media to pink billboards, it's suddenly 'hot' to discuss gut ...
    Jul 7, 2022 · A BelliWelli billboard above traffic in Los Angeles declares “Hot girls have IBS.” The billboards went viral in late 2021, and have been erected in three other ...
  118. [118]
    Small intestine 3: Absorption (video) - Khan Academy
    Aug 7, 2016 · This video explains the absorption process of monomers in our body. It details how amino acids, sugars, nucleosides, and fats are transported into cells.
  119. [119]
    Celiac Awareness Month - Celiac Disease Foundation
    Shine a Light on Celiac Disease Awareness​​ Since 2020, we've united globally to shine a light—literally—by illuminating landmarks to highlight the urgent need ...Missing: 2020s | Show results with:2020s
  120. [120]
    28 Proclamations Declare May as Celiac Awareness Month
    May 22, 2025 · Every May, the Celiac Disease Foundation leads a powerful national movement to raise awareness for the more than 3 million Americans living ...Missing: 2020s | Show results with:2020s
  121. [121]
    Metaphors of the Gut. Poetic Musings on Emotional Digestion
    Jan 26, 2024 · Metaphors of the gut in the poetry that expands. Emotional digestion, a nuanced art, In the language of the belly, where emotions depart.
  122. [122]
    [PDF] “Nature's stomach”: emersoN, WhitmaN, aNd the Poetics of digestioN
    Whitman culminates his metaphor of eating emerson's writing by extending the figure to Page 2 98 its digestive conclusion: “suppose these books becoming absorb ...
  123. [123]
    Ethical Issues in Pediatric Small Bowel Transplantation - SpringerLink
    May 26, 2016 · Small bowel transplantation and short bowel syndrome are fields where many ethical issues come to light and leave clinicians with some moral ...Missing: intestine transplant debates
  124. [124]
    Social media's gut feeling is all wrong: there is no fast track to a ...
    Mar 4, 2025 · A diet high in fibre from different food sources is far more effective for maintaining a healthy gut than supplements and online fads, experts say.
  125. [125]
    Decoding gut health trends on social media | Content for the lay public
    Mar 25, 2024 · There are a lot of misinformed trends that take off on TikTok, claiming to heal your gut without providing scientific evidence.