There are two major steps in gastrointestinal (GI) development: the formation of the gut tube and the formation of individual organs each with its own specialized cell types (1). The endoderm is the precursor to the gastrointestinal epithelial lining, and endodermal development requires multiple factors such as GATA transcription factors and WNT signaling (2,3). Multiple interactions occur between the endoderm, mesoderm, and ectoderm during development, involving a variety of signaling cascades including the Hedgehog, Hh, Bmp, FGF, and Wnt pathways (4,5,6,7). The endoderm induces the mesoderm, conferring on it a dorsal -ventral pattern. Endoderm and ectoderm contact one another in the 2- to 4-week embryo, with the endoderm forming the yolk sac roof. A primitive gut forms in the 3rd to 8th weeks secondary to cephalocaudal and lateral foldings that incorporate the dorsal endodermally lined yolk sac cavity. The amnion and yolk sac communicate through the neuroenteric canal (Fig. 6.1). The neuroenteric canal closes and the notochord grows forward, becoming intercalated within the endoderm. The neural tube then separates from the ectoderm. Mesoderm surrounds the notochord, separating the ectoderm and endoderm (8). Splanchnic mesoderm surrounding the primitive gut forms the muscular and connective tissue layers. The former yolk sac elongates under the developing nervous system to form the primitive foregut anteriorly and the primitive hindgut posteriorly. The central portion develops into the midgut, which has a free communication with the yolk sac (the vitellointestinal duct). The anterior abdominal wall develops by simultaneous cranial, caudal, and lateral infoldings, which attenuate the yolk sac, causing it to become intracoelomic in location (Fig. 6.1). The foregut is short at first, lying closely apposed to the developing vertebrae, and it becomes suspended by a short mesentery. The foregut gives rise to the esophagus, stomach, duodenum as far as the ampulla of Vater, liver, pancreas, and respiratory system, and it has its own arterial blood supply deriving from the celiac axis (9).

The duodenum distal to the bile duct, and the jejunum, ileum, cecum, ascending colon, and proximal one half to two thirds of the transverse colon derive from the midgut and are supplied by the superior mesenteric artery. At about the 5- to 12-mm stage, the midgut lengthens, becoming tubular and growing away from the vertebral axis. It then coils, inducing dorsal mesenteric development. During the 5th fetal week, the midgut is “U” shaped and suspended by a dorsal mesentery distributed around the superior mesenteric artery. The apex of the intestinal loop communicates with the vitelline duct, which rapidly decreases in size. During the 5th to 6th fetal weeks, increases in intestinal length, along with the disproportionate amount of abdominal space occupied by the fetal liver, cause the intestines to herniate into a mesotheliallined sac within the umbilical cord (9). The cecum develops on the caudal limb and the vitellointestinal duct lies at the apex. A small portion of the caudal limb, between the attachment of the vitellointestinal duct and cecum, forms the terminal ileum. The midgut starts sliding back into the abdomen between the 10th and 12th fetal weeks, a process accomplished in three phases (Fig. 6.2). The first is a 90-degree counterclockwise rotation around the superior mesenteric artery. The second occurs at about the 10th week, when there is enough room for the bowel to return to the abdominal cavity. The cranial loop of the small bowel reenters the abdomen, first passing to the right of the superior mesenteric artery and rotating a further 180 degrees, thereby making the total rotation 270 degrees. Small intestinal loops fill the central abdomen.

Although an anatomically distinguishable intestinal tract develops early in embryonic life, functional absorptive cells do not appear until later in gestation. Intestinal differentiation occurs along a proximal-to-distal gradient.
The epithelium develops from simple endodermal tubules early in embryogenesis (1) appearing as a multilayered sheet of undifferentiated endodermal cells with short microvilli. Deeper cells do not demonstrate any polarity; mitoses occur throughout the epithelium. Villous formation with mesenchymal infiltration into the villous core begins at the ninth gestational week. Between 9 and 10 weeks, the stratified epithelium converts to a simple columnar epithelium (1). The progenitor cell region, which gives rise to the crypts, localizes to the intervillous
area (10). Villi are long and tapering by 20 weeks, and the muscle coats are obvious at this time. Enterocyte proliferation occurs along the entire villous length until several days before birth.

Enterocyte differentiation depends on the cell position along both the vertical (crypt-villus) axis as well as the location along the horizontal (proximal to distal) axis of the GI tract. Functional differences along both the vertical and the horizontal axes (11) reflect both different patterns of gene expression and the presence of multiple epithelial cell types. The basis for regional differences in gene expression results from differences in the transcription factors that interact with the promoter and enhancer region of these genes. Homeobox genes participate in establishing differentiation gradients during development and then maintaining these patterns in adult tissues. The epithelium finishes its morphologic differentiation into enterocytes, goblet cells, endocrine cells, and Paneth cells in the 4 to 5 days prior to birth. Expression of genes characteristic of terminally differentiated cell processes relies on transcription factors such as Math1 and Cdx2 (12,13,14).

Primordial intestinal lymphoid structures appear approximately halfway through gestation. At the time of birth, Peyer patches have the greatest density of any proliferating lymphoid tissue in the body although the lamina propria contains relatively few lymphocytes and plasma cells at this stage (Fig 6.3). T- and B-cell aggregates form early Peyer patches by 16 weeks’ gestation, and by 19 weeks, organized Peyer patches are present. T cells populate the lamina propria and epithelium from 11 weeks’ gestation and increase in number thereafter. Following birth, there is a marked increase in the number of Peyer patches, reflecting the initial response of the host immune system to environmental antigens passing through the intestinal tract.

The intestinal mucosa is in continuous contact with food antigens, the enteric commensal bacteria that constitute the normal gut flora, and potential pathogens that enter the host through the intestine. The upper intestinal bacterial count is normally low, and it increases as one progresses distally. Bacterial numbers are kept low by intestinal motility, mucus, and the antibacterial effects of pancreatic and biliary juice and gastric acid (Fig. 6.4). This resident microflora maintains a stable environment and eliminates pathogenic organisms by producing antimicrobial substances and short-chain fatty acids and other metabolites. It also stimulates mucosal epithelial growth by providing absorbable nutrients (15,16).

The small intestinal mucosa forms a barrier to the unimpeded movement of antigens, microorganisms, and potentially injurious substances from the lumen to the internal environment. A single layer of columnar epithelium, held together by tight junctions, lies on an intact basement membrane. Intercellular tight junctions, which are impermeable to large molecules and bacteria, help maintain epithelial integrity and prevent the entry of foreign material. The tight junctions are specialized membrane domains at the apical pole of the cells that not only create a primary barrier to prevent paracellular transport of solutes (barrier function) but also restrict the lateral diffusion of membrane lipids and proteins to maintain cellular polarity (gate function) (17). The tight junction complexes form a complete ring around
the apical pole of the cells. Tight junction permeability is plastic and can be altered by extracellular stimuli such as inflammatory mediators, drugs, and microorganisms (18). In addition, an unstirred water layer, varying from 25 to 170 &mgr;m in thickness, covers the epithelium and may regulate diffusion of other molecules (19).

The proximal duodenal mucosa transports bicarbonate into an adherent mucus layer in a manner similar to that seen in the stomach, providing a protective barrier from damage caused by pepsin and acid (20). The alkaline pH environment beneath the mucin layer acts as a buffer and a lubricant. The mucus protects against microbial adherence to the epithelium and resists digestion by intraluminal enzymes. Mucus secretion is stimulated by immune complexes, chemical agents, soluble mediators, histamine, lymphokines, and neurotransmitters (21). Nitric oxide plays an important role in modulating duodenal fluid and bicarbonate secretion (22). The secreted mucus contains albumin; immunoglobulin, particularly secretory IgA; &agr;₁-antitrypsin; lysozyme; lactoferrin; and EGF. Secretory IgA in the intestinal lumen acts in concert with nonspecific host defenses, including mucin, bacteriocidins, defensins, and lytic cells (23), to protect the host by neutralizing or excluding antigens, toxins, and organisms and regulating commensal bacteria (24). Granulocytes, macrophages, and Paneth cells act as intramucosal phagocytes.

The human small intestine, which extends from the gastric pylorus to the ileocecal valve, measures about 7 m in length. The C-shaped duodenum encloses the head of the pancreas in its concavity. It measures approximately 20 to 25 cm in length and, except for its first part, lies in the retroperitoneum. The first part of the duodenum measures approximately 5 cm in length, and it ascends posteriorly from the pylorus to the right. It lies above and anterior to the head of the pancreas, below the gallbladder, and anterior to the common bile duct, gastroduodenal artery, and portal vein. The second portion measures approximately 7 cm in length and is covered by the peritoneum of the infracolic compartment of the peritoneal cavity, which separates it from coils of the small bowel. The transverse colon and its mesentery cross it. The hilum of the right kidney and right renal vessels lie behind it, and the bodies of the lumbar vertebrae and inferior vena cava lie medially.

The common bile duct and pancreatic duct enter the second part of the duodenum posteromedially at the ampulla of Vater approximately 9 to 10 cm from the pyloric ring (Fig. 6.5). In most patients, the common bile duct and pancreatic duct join before draining into the ampulla (Fig. 6.6), but in about 10% of cases, the bile duct and pancreatic duct open separately into the intestinal lumen. In about 30% of patients, an accessory, more proximal pancreatic duct drains into the duodenal lumen. Both the bile duct and the pancreatic duct have their own muscular coats. A cross section through this area of the duodenum contains numerous ramifying ducts in all layers of the duodenal wall (Fig. 6.7). The sphincter of Oddi at the ampulla of Vater measures approximately 9.5 mm in length (25).

The third part of the duodenum arches transversely across the vena cava and aorta at the level of the body of the third lumbar vertebra. It is 7 to 9 cm in length. The root of the mesentery obliquely crosses its terminal portion. It is also crossed by the superior mesenteric artery and vein. Superiorly, it relates to the pancreatic uncinate process. The fourth part of the duodenum varies in length and is difficult to distinguish from the third part. It curves up to the left to the duodenojejunal flexure, where it is attached by a suspensory duodenal ligament, the ligament of Treitz.

Although the duodenum has a fairly constant length, the length of the rest of the small intestine is not as clearly established. Measurements taken at autopsy suggest adult lengths between 300 and 900 cm with a mean of approximately 600 cm. Other measurements taken during life give
a much shorter length of 280 cm. The mesentery supporting the small intestine fans out from an origin only 15 to 20 cm long. The mesentery runs along an oblique line crossing the posterior abdominal wall from the left to right, from the duodenojejunal flexure to the right iliac fossa.

There is no recognizable line of division between the three parts of the small intestine: duodenum, jejunum, and ileum. Traditionally, the jejunum represents the proximal 40 cm after the ligament of Treitz and the ileum the distal 60 cm of the small intestine. The lumen of the jejunum is wider than that of the ileum, and its wall is thicker due to prominent circular mucosal folds, known as folds of Kerckring (Fig. 6.8). These folds run parallel to the longitudinal axis of the bowel, are most prominent between the mid duodenum and jejunum, and are absent in the distal ileum. They contain both the mucosa and the underlying submucosa.

The duodenum is supplied by the celiac and superior mesenteric arteries (Fig. 6.9). The celiac trunk branches into the gastroduodenal artery. The superior mesenteric artery supplies the jejunum, cecum, and appendix, traveling through the mesentery in several major branches (Fig. 6.10). Ten to fifteen jejunoileal arteries arise from the left side of the superior mesenteric artery, which originates 1 to 2 cm below the celiac artery. Each divides into two branches, which join adjacent branches to form a series of arcades. These in turn branch and form a second series of arcades before the vasa recta penetrate the intestinal wall (26). The ileocolic artery, which arises from the lower superior mesenteric artery, supplies the terminal ileum, cecum, appendix, and proximal ascending colon. It anastomoses with the right colic artery. This and subsequent branches form complex arcades.

Intramural arteries enter the intestinal serosa and pierce the muscularis propria to form an extensive submucosal vascular plexus (Fig. 6.11). The submucosal arterial plexus gives rise to arterioles, which supply the mucosa, submucosa, and muscular layers. However, the mucosal capillary bed is isolated from that of the muscularis propria. The capillary bed in the muscularis mucosae has two layers (27). These two groups of arteries make their way into the mucosa. Some ramify on the luminal side of the muscularis mucosae and give rise to a capillary network that surrounds the crypts. Others continue into the villus, entering it at its base before arborizing into a dense capillary network. A rich network of blood capillaries ramifies through the lamina propria and is closely apposed to the epithelial basement membranes (Figs. 6.12 and 6.13). Villi are more highly vascularized than are the crypts (28). The mucosa receives approximately 75% of the intestinal blood flow. The bowel can autoregulate its blood flow, which means that it maintains a constant blood flow in the face of fluctuating arterial pressures. Following

eating, small intestinal blood flow increases by over 100%, with the majority of the blood flow being diverted to the mucosa.

Villous capillaries drain into a single venule that starts high in the villus. One or two veins form in each villus. These course downward, eventually joining veins at the crypt bases and merging with veins draining into the submucosal plexus. These vessels continue on through the muscularis propria and serosa, merging with other veins draining into the portal vein via the superior mesenteric vein. The superior mesenteric vein receives its drainage from the distal duodenum, jejunum, ileum, appendix, and cecum, as well as the ascending and transverse colon. Venous drainage of the duodenum parallels its arterial supply. Inferior pancreaticoduodenal veins drain to the right gastroepiploic vein. The major veins draining the GI tract form the portal system (Fig. 6.14). The portal vein forms by the junction of the splenic vein and the superior mesenteric vein. The portal vein receives direct input from the right and left gastric veins, superior pancreaticoduodenal vein, accessory pancreatic vein, and pyloric vein. Blood in the portal vein is carried to the liver, where nutrients are absorbed and processed.

Lymphatic drainage starts with the central lacteal, which drains into the submucosal lymphatic plexus (Figs. 6.12 and 6.15). The broad proximal villi contain two to five lacteals, whereas more distal thin villi contain only one. Lacteals measure 5 to 15 &mgr;m in diameter and run parallel to one another in the longitudinal direction of the villus. The endothelial lining contains gaps and has overlapping areas with adjacent endothelial cells through which chylomicron particles containing newly absorbed lipids can pass (29). The wall of the lacteal consists of endothelium and a reticulin fiber sheath to which smooth muscle fibers attach (Fig. 6.15) (30). Villi intermittently contract and shorten due to the activity of the smooth muscle cells. These contractions force lymph from the central lacteal into the basal lymphatics. The central lacteal is also completely surrounded by the subepithelial blood capillary network (Fig. 6.15). Lacteals anastomose with each other, which forms an expanded sinus. In the fasted state, lacteals are difficult to see.

There are many blind-ending lymphatics in the upper part of the interfollicular area. These gradually fuse and form perifollicular lymphatic sinuses surrounding the lateral surfaces and bottoms of Peyer patch follicles. Between the perifollicular lymphatic networks and the interfollicular area are many high endothelial venules (HEVs) that connect to capillaries in the dome and follicle. The close association of HEVs with perifollicular lymphatics facilitates prompt drainage of fluid and keeps macromolecules from leaking out of HEVs during lymphocyte migration into the lymphatics. At the villous base, lymphatics empty into thicker lymphatics that then connect to form a flat, wide sinus (the intravillous lymphatic sinus). From the base of each sinus, several lymphatics descend perpendicularly to drain into submucosal lymphatics that run transversely beneath the muscularis mucosae to form a two-layer meshwork. The submucosal lymphatic plexus drains into large subserosal lymphatics (31) that drain into large conducting mesenteric lymphatics eventually flowing into the cisterna chyli.

Draining lymph nodes consist of the pancreaticolienal group lying along the splenic artery, the pyloric group lying along the gastroduodenal artery, and the superior mesenteric nodes. Small pancreaticoduodenal nodes lie scattered along the artery of the same name. The lymphatics also drain into the small pyloric nodes superiorly and preaortic lumbar nodes inferiorly. Pyloric nodes drain to the hepatic nodes along the common hepatic artery. Others drain to the root of the superior mesenteric lymph nodes, following the distribution of the superior mesenteric artery and draining the areas supplied by it. Small mesenteric lymph nodes lie along the vasa recta of the mesentery, adjacent to the bowel wall, and larger ones lie along the primary arcades and the intestinal arteries. There are about 200 mesenteric lymph nodes. Two major groups of ileocolic lymph nodes drain the terminal ileum and cecum: one near the bowel wall and another at the origin of the ileocolic artery.

The innervation of the small bowel resembles that of the large intestine described in Chapter 13. The intrinsic innervation is discussed in Chapter 10.

Erosive duodenitis may develop in patients subjected to severe stress or in those consuming large quantities of alcohol. Acute erosive duodenitis and duodenal ulcers may also develop within a matter of hours in severely burned patients (Fig. 6.72). In these situations, the mucosal barrier breaks down, mediated in part by transient intestinal hypoperfusion and increased intestinal permeability. The duodenum appears diffusely hemorrhagic and reddened, usually in conjunction with similar changes in the stomach (Fig. 6.73). Erosive duodenitis begins as areas of localized interstitial edema (Fig. 6.74). Early enterocyte damage consists of cytoplasmic vacuolization with eventual epithelial loss. Enterocytes contain enlarged, hyperchromatic nuclei with prominent nucleoli, syncytial changes, and cytoplasmic tufting. The villi degenerate, the crypts become hyperplastic, and the epithelial cells become mucin depleted and cuboidal in shape. Neutrophils, lymphocytes, plasma cells, and sometimes eosinophils infiltrate the mucosa and the lamina propria (Fig. 6.75). The stroma may exhibit prominent telangiectasia. These evolve with red cell extravasation and the development of erosions and full-blown ulcers. Often, it is very difficult to distinguish the nonspecific effects of stress duodenitis from those of peptic duodenitis.

Ischemic injury to the small bowel forms a continuum of changes secondary to tissue anoxia that range from epithelial cellular dysfunction to frank necrosis (Fig. 6.81). The clinical severity of ischemic enteritis varies widely from silent transient episodes to massive and sometimes fatal hemorrhagic infarctions. Vascular occlusion and periods of hypotension or vasoconstriction account for most cases of intestinal ischemia. The most common clinical scenario is an elderly individual with underlying cardiovascular disease. However, intestinal ischemia may also affect individuals of any age, including infants, in the setting of various vasculopathies, some infections, intussusception and torsion, and certain drug therapies (Table 6.5).

All forms of ischemic damage share the underlying feature that the blood supply fails to meet the local tissue demands required to fulfill normal functions and/or maintain normal structure. Prolonged cessation of blood flow inevitably results in cell death because of the diminished delivery of oxygen and metabolic substrates and the accumulation of potentially cytotoxic end products of anaerobic metabolism. Small intestinal blood supply has to be reduced by greater than 50% to induce detectable tissue injury (131). The extent and duration of the ischemia depends on several factors, including the nature of the intestinal vasculature, luminal bacterial virulence, and the duration of the ischemic episode. The first detectable sign of ischemic injury is increased capillary permeability. With continuing ischemia, detectable epithelial cell injury occurs. Mucosal cells are shed at an increased rate, and damage to the plasma membrane of unshed cells results in leakage of cytoplasmic digestive enzymes and tryptic digestion of the mucosa. Necrosis and subsequent bacterial invasion develop when the mucosal barrier becomes defective. The basic pathologic response to ischemia is mucosal coagulative necrosis. If reflow is reestablished, acute inflammation develops.

No single process represents the critical event in ischemic injury. Depletion of cellular energy stores and accumulation of toxic metabolites both contribute to cell death. Reestablishing the blood flow (reperfusion) is required to reverse the injury because it allows cellular regeneration and washout of toxic metabolites. However, reperfusion of ischemic tissues also paradoxically injures the tissues (Fig. 6.82) (183). In fact, most of the injury that occurs in intestinal ischemia occurs during the reperfusion period due to the production of reactive oxygen metabolites, including O₂^–, H₂O₂, OH, HOCl, and certain n-chloramines, by activated neutrophils and other inflammatory cells, as a result of the reintroduction of oxygen (132). Superoxide and hydrogen peroxide increase mucosal and vascular permeability, recruit
and activate neutrophils, and act as the precursors of more damaging hydroxyl radicals via the Fenton and myeloperoxidase reactions (Fig. 6.82) (133).

The hypoxia induces endothelial cells to produce various adhesion molecules, including integrins and selectins, which promote the adherence, transendothelial migration, and activation of leukocytes and platelets.

Acute mesenteric infarctions result from mesenteric arterial occlusion (Fig. 6.83), nonocclusive low-flow states, mesenteric vein thrombosis (Fig. 6.84), or vasculitis.