Digestive System Anatomy and Physiology: Part 1 PDF

Summary

This document provides an overview of the digestive system, starting with a look at the alimentary canal and accessory digestive organs. It details the structure and function of key organs like the mouth, esophagus, stomach, and small intestine. The document also touches on homeostasis imbalance in the digestive system.

Full Transcript

The Digestive System and Body Metabolism

PART I: ANATOMY AND PHYSIOLOGY OF THE DIGESTIVE SYSTEM

14.1 Anatomy of the Digestive System

We can separate the organs of the digestive system into two main groups:
those forming the *alimentary* (al0e˘-men9tar-e; *aliment* 5 nourish)
*canal* and the *accessory digestive organs* **(Figure 14.1)**. The
alimentary canal performs the whole menu of digestive functions
(ingests, digests, absorbs, and defecates) as it propels the foodstuffs
along its length. The accessory organs(teeth, tongue, and several large
digestive glands) assist digestion in various ways, as described
shortly.

14.1a Organs of the Alimentary Canal

The alimentary canal, also called the gastrointestinal (GI) tract or
*gut*, is a continuous, coiled, hollow muscular tube that winds through
the ventral body cavity from mouth to anus. Its organs are the *mouth*,
*pharynx*, *esophagus*, *stomach*, *small intestine*, and *large*
*intestine*. The large intestine leads to the terminal opening, or
*anus*. In a cadaver, the alimentary canal is approximately 9 m (about
30 feet) long, but in a living person, it is considerably shorter
because of its muscle tone. Food material within this tube is
technically outside the body, because it has contact only with cells
lining the tract and the tube is open to the external environment at
both ends. This relationship becomes clearer if you think of your
alimentary canal as an elongated doughnut. Then it's easy to see that if
you stick your finger through a doughnut hole, your finger is not really
*in* the doughnut. Each organ of the alimentary canal is described next
(find the organs in Figure 14.1).

**Mouth**


Food enters the digestive tract through the mouth, ororal cavity, a
mucous membrane--lined cavity **(Figure** **14.2)**. The lips, or labia,
protect its anterior opening; the cheeks form its lateral walls; the
hard palate forms its anterior roof; and the soft palate forms its
posterior roof. The uvula (u9vu-lah) is a fleshy fingerlike projection
of the soft palate, which dangles from the posterior edge of the soft
palate. The space between the lips and cheeks externally and the teeth
and gums internally is the vestibule. The area contained by the teeth is
the oral cavity proper. The muscular tongue occupies the floor of the
mouth. The tongue has several bony attachments--- two of these are to
the hyoid bone and the styloid processes of the skull. The lingual
frenulum (ling9gwal fren9u-lum), a fold of mucous membrane, secures the
tongue to the floor of the mouth and limits its posterior movements (see
Figure 14.2a).

**Homeostatic Imbalance 14.1**

**Pharynx**

From the mouth, food passes posteriorly into the *oropharynx* and
*laryngopharynx*, both of which are common passageways for food, fluids,
and air. The pharynx is subdivided into the *nasopharynx*, part of the
respiratory passageway; the oropharynx, posterior to the oral cavity;
and the laryngopharynx, which is continuous with the esophagus
inferiorly (see Chapter 13).

The walls of the pharynx contain two skeletal muscle layers. The cells
of the outer layer run longitudinally; those of the inner layer (the
constrictor muscles) run around the wall in a circular fashion.
Alternating contractions of these two muscle layers propel food through
the pharynx inferiorly into the esophagus. Later we describe this
propelling mechanism, called *peristalsis* (per0 ı˘-stal9sis).

**Esophagus**

The esophagus (e˘-sof 9ah-gus), or *gullet*, runs from the pharynx
through the diaphragm to the stomach. About 25 cm (10 inches) long, it
is essentially a passageway that conducts food (by peristalsis) to the
stomach.

The walls of the alimentary canal organs from the esophagus to the large
intestine are made up of the same four tissue layers, or tunics
(**Figure 14.3**, p. 486):

1\. The mucosa is the innermost layer, a moist mucous membrane that lines
the hollow cavity, or lumen, of the organ. It consists primarily of
*surface epithelium* plus a small amount of connective tissue (*lamina
propria*) and a scanty *smooth muscle layer*. Beyond the esophagus,
which has a friction-resisting stratified squamous epithelium, the
epithelium is mostly simple columnar.

2\. The submucosa is found just beneath the mucosa. It is soft connective
tissue containing blood vessels, nerve endings, mucosa-associated
lymphoid tissue (MALT), and lymphatic vessels.

3\. The muscularis externa is a muscle layer typically made up of an
inner *circular layer* and an outer *longitudinal layer* of smooth
muscle cells.

4\. The serosa is the outermost layer of the wall. As half of a serous
membrane pair, the visceral peritoneum (per0ı˘-to-ne9um) consists of a
single layer of flat, serous fluid--producing cells. The visceral
peritoneum is continuous with the slippery parietal peritoneum, which
lines the abdominopelvic cavity by way of a membrane extension, the
mesentery (mes9en-ter0e). A mesentery is formed when two layers of
peritoneum are fused together. Routes for nerves, blood vessels, and
lymphatic vessels are found between the layers. Mesenteries anchor
digestive organs in place and store fat. (These relationships are
illustrated in Figure 14.5 on p. 488.)

**Homeostatic Imbalance 14.2**

The alimentary canal wall contains two important *intrinsic nerve
plexuses*---the submucosal nerve plexus and the myenteric (mi-en9ter-ik;
"intestinal muscle") nerve plexus. These networks of nerve fibers are
actually part of the autonomic nervous system. They help regulate the
mobility and secretory activity of GI tract organs.

**Stomach**


The C-shaped stomach **(Figure 14.4)** is on the left side of the
abdominal cavity, nearly hidden by the liver and diaphragm. Different
regions of the stomach have been named. The *cardial region*, or
*cardia* (named for its position near the heart), surrounds the
cardioesophageal (kar0de-o-e˘-sof 0ahje9al) sphincter, through which
food enters the stomach from the esophagus. The *fundus* is the expanded
part of the stomach lateral to the cardial region. The *body* is the
midportion of the stomach; in the body, the convex lateral surface is
the greater curvature, and its concave medial surface is the lesser
curvature. As it narrows inferiorly, the body becomes the *pyloric
antrum* and then the funnelshape *pylorus* (pi-lor9us), the terminal
part of the stomach. The pylorus is continuous with the small intestine
through the pyloric sphincter, or pyloric valve.

The stomach varies from 15 to 25 cm (6 to 10 inches) in length, but its
diameter and volume depend on how much food it contains. When it is
full, it can hold about 4 liters (1 gallon) of food. When it is empty,
it collapses inward on itself, and its mucosa is thrown into large folds
called rugae (roo9ge; *ruga* 5 wrinkle, fold). The lesser omentum
(o-men9tum), a double layer of peritoneum, extends from the liver to the
lesser curvature of the stomach. The greater omentum, another extension
of the peritoneum, drapes downward and covers the abdominal organs like
a lacy apron before attaching to the posterior body wall **(Figure
14.5)**. The greater omentum is riddled with fat, which helps to
insulate, cushion, and protect the abdominal organs. It also has large
collections of lymphoid follicles containing macrophages and defensive
cells of the immune system. The stomach acts as a temporary "storage
tank" for food as well as a site for food breakdown. Besides the usual
longitudinal and circular muscle layers, its wall contains a third,
obliquely arranged layer in the *muscularis externa* (see Figure 14.4a).
This arrangement allows the stomach not only to move food along the
tract, but also to churn, mix, and pummel the food, physically breaking
it down into smaller fragments. In addition, chemical breakdown of
proteins begins in the stomach.

The mucosa of the stomach is a simple columnar epithelium composed
entirely of mucous cells. They produce a protective layer of
bicarbonate-rich alkaline mucus that clings to the stomach mucosa and
protects the stomach wall from being damaged by acid or digestive
enzymes. This otherwise smooth lining is dotted with millions of deep
gastric pits, which lead into gastric glands (Figure 14.4c) that secrete
the components of gastric juice. For example, some stomach cells produce
intrinsic factor, a substance needed for absorption of vitamin B12 in
the small intestine. The chief cells produce inactive proteindigesting
enzymes, mostly pepsinogens. The parietal cells produce corrosive
hydrochloric acid (HCl), which makes the stomach contents acidic and
activates the enzymes, as in the conversion of pepsinogen to pepsin
(shown in Figure 14.4d). The *mucous* *neck cells* produce a thin acidic
mucus with an unknown function that is quite different from that
secreted by the mucous cells of the mucosa. Still other cells, the
enteroendocrine cells (*entero* 5 gut), produce local hormones, such as
*gastrin*, that are important in regulating the digestive activities of
the stomach (see **Table 14.1**).

Most digestive activity occurs in the pyloric region of the stomach.
After food has been processed in the stomach, it is thick like heavy
cream and is called chyme (kıˉm). The chyme enters the small intestine
through the pyloric sphincter.

**Small Intestine**

The small intestine is the body's major digestive organ. Within its
twisted passageways, usable nutrients are finally prepared for their
journey into the cells of the body. The small intestine is a muscular
tube extending from the pyloric sphincter to the large intestine (see
Figure 14.1, p. 483). It is the longest section of the alimentary tube,
with an average length of 2 to 4 m (7 to 13 feet) in a living person.
Except for the initial part of the small intestine, which mostly lies in
a retroperitoneal position (posterior to the parietal peritoneum), the
small intestine hangs in sausagelike coils in the abdominal cavity,
suspended from the posterior abdominal wall by the fan-shaped mesentery
(Figure 14.5b, p. 488). The large intestine encircles and frames it in
the abdominal cavity.

The small intestine has three subdivisions: the duodenum (doo0uh-de9num;
"twelve finger widths long"), the jejunum (je˘-joo9num; "empty"), and
the ileum (il9e-um; "twisted intestine"), which contribute 5 percent,
nearly 40 percent, and almost 60 percent of the length of the small
intestine, respectively (see Figure 14.1). The ileum joins the large
intestine at the ileocecal (il0e-o-se9kal) valve (look ahead to Figure
14.8, p. 493).


Chemical digestion of foods begins in earnest in the small intestine.
The small intestine is able to process only a small amount of food at
one time. The *pyloric sphincter* (literally, "gatekeeper") controls the
movement of chyme into the small intestine from the stomach and prevents
the small intestine from being overwhelmed. In the C-shaped duodenum,
some enzymes are produced by the intestinal cells. More important are
enzymes that are produced by the pancreas and then delivered to the
duodenum through the pancreatic ducts, where they complete the chemical
breakdown of foods in the small intestine. *Bile* (formed by the liver)
also enters the duodenum through the bile duct in the same area
**(Figure 14.6)**. The main pancreatic and bile ducts join at the
duodenum to form the flasklike *hepatopancreatic ampulla*
(he˘-pa˘″to-pan-kre-a˘9tik am-pu9lah), literally, the "liver-pancreatic
enlargement." From there, the bile and pancreatic juice travel through
the *duodenal papilla* and enter the duodenum together.

Nearly all nutrient absorption occurs in the small intestine. The small
intestine is well suited for its function. Its wall has three structures
that increase the absorptive surface area tremendously---villi,
microvilli, and circular folds **(Figure 14.7)**. Villi are fingerlike
projections of the mucosa that give it a velvety appearance and feel,
much like the soft nap of a towel. Within each villus is a rich
capillary bed and a modified lymphatic capillary called a lacteal. The
nutrients are absorbed through the mucosal cells into both the
capillaries and the lacteal (indicated in Figure 14.13 on p. 499).
Microvilli (mi0kro-vil9i) are tiny projections of the plasma membrane of
the mucosa cells that give the cell surface a fuzzy appearance,
sometimes referred to as the brush border. The plasma membranes bear
enzymes (*brush border* *enzymes*) that complete the digestion of
proteins and carbohydrates in the small intestine. Circular folds also
called plicae circulares (pli9se ser-ku-la9res), are deep folds of both
mucosa and submucosa layers.Unlike the rugae of the stomach, the
circular folds do not disappear when food fills the small intestine.
Instead, they form an internal "corkscrew slide" to increase surface
area and force chyme to travel slowly through the small intestine so
nutrients can be absorbed efficiently. All these structural
modifications (villi, microvilli, circular folds), which increase the
surface area, decrease in number toward the end of the small intestine.
In contrast, local collections of lymphatic tissue (called Peyer's
patches) found in the submucosa increase in number toward the end of the
small intestine. This reflects the fact that the remaining (undigested)
food residue in the intestine contains huge numbers of bacteria, which
must be prevented from entering the bloodstream if at all possible.

**Large Intestine**


The large intestine is much larger in diameter than the small intestine
(thus its name) but shorter in length. About 1.5 m (5 feet) long, it
extends from the ileocecal valve to the anus **(Figure 14.8)**. Its
major functions are to dry out the indigestible food residue by
absorbing water and to eliminate these residues from the body as feces
(fe9sˉez). It frames the small intestine on three sides and has these
subdivisions: *cecum* (se9kum), *appendix*, *colon*, *rectum*, and *anal
canal*.

The saclike cecum is the first part of the large intestine. Hanging from
the cecum is the wormlike appendix, a potential trouble spot. Because it
can easily become obstructed, it is an ideal location for bacteria to
accumulate and multiply. Inflammation of the appendix, appendicitis, is
the usual result.

The colon is divided into several distinct regions. The ascending colon
travels up the right side of the abdominal cavity and makes a turn, the
*right colic* (or *hepatic*) *flexure*, to travel across the abdominal
cavity as the transverse colon. It then turns again at the *left colic*
(or *splenic*) *flexure* and continues down the left side as the
descending colon to enter the pelvis where it becomes the S-shaped
sigmoid (sig9moyd) colon. The sigmoid colon, rectum, and anal canal lie
in the pelvis.

The anal canal ends at the anus (a9nus), which opens to the exterior.
The anal canal has two valves: the external anal sphincter, composed of
skeletal muscle, is voluntary, and the internal anal sphincter, formed
by smooth muscle, is involuntary. These sphincters, which act rather
like purse strings to open and close the anus, are ordinarily closed
except during defecation, when feces are eliminated from the body.

Because most nutrients have been absorbed before the large intestine is
reached, no villi are present in the large intestine, but there are
tremendous numbers of *goblet cells* in its mucosa that produce alkaline
(bicarbonate-rich) mucus. The mucus lubricates the passage of feces to
the end of the digestive tract.

In the large intestine, the longitudinal layer of the muscularis externa
is reduced to three bands of muscle called *teniae coli* (ten9ne-e
ko9li; "ribbons of the colon"). Because these muscle bands usually
display some degree of tone (are partially contracted), they cause the
wall to pucker into small pocketlike sacs called haustra (haws9trah).