How Does Digestion Work and How Can I Improve Mine? Introduction

The food you eat contains the nutrients that serve as building blocks, and provide energy and nourishment throughout your body. In food, nutrients are contained in large molecules that are chemically and physically bound together. Digestion is the process of breaking down these tightly bound molecules into individual nutrients that can be taken into your body and used to support its functions. Simply defined, digestion is cutting things down to a size in which they can be absorbed into your body.

Digestion occurs in the gastrointestinal tract-the 20 to 30 foot long tube extending from your mouth to your anus. Whatever you eat flows through this system, but until it is absorbed through the intestinal tract, the nutrients in food are physically outside of your body. This is because the gastrointestinal tract functions like an internal skin and provides a barrier between whatever you ingest from the outside (external) world and your internal bloodstream and cells. Part of the digestion process, then, is the selective transport of nutrients through the cell wall that lines your intestinal tract. Once transported across the intestinal barrier to the inside of your body, these nutrients can enter your bloodstream and circulate to all of your tissues to maintain organ function, support your need for energy, and provide for growth and repair of new cells and tissues.

While digestion can be simply defined, its mechanics are quite complex. This is because your food contains so many different sizes, shapes, and types of individual molecules, all tightly entwined, and because each of these types of molecules is chemically distinct. Digestion uses both mechanical processes, such as chewing and grinding, which help separate the different types of molecules, as well as chemical processes, in the form of enzymes that can cut the bonds within the molecules, to release small nutrients into your system. An analogy is two or more necklace chains of different types twisted, knotted, and interlocked together. Digestion would be the process of untwisting and separating the chains, usually requiring cutting them in a couple of places, and then pulling them apart and further cutting each of them into many smaller pieces, so they can become building blocks for other necklace chains.

Food is Complex and Contains Many Types of Molecules


Food is a very complex mixture of different types of very large molecules-the proteins and some carbohydrates; mid-range sized molecules-such as fats; and a wide variety of smaller molecules including vitamins, minerals, small carbohydrates like sugars, and other phytonutrients, which are protective substances found in plants (phyto = plant). Most foods you eat are a mixture of all of these different molecules, and since you need a variety of types of nutrients, your body must be able to digest these varied types of molecules in food.

The size, as well as the type of molecule, makes a difference in how a food is digested, the nutrients that are derived from it, and where these nutrients are taken up by your body. Each type of molecule has its own challenge with respect to digestion.

Proteins Provide Amino Acid Building Blocks For Growth and Repair

Proteins are extremely important because they constitute the majority of the structural tissue in your body, such as bone and connective tissues that provide the shape and form to which your cells attach. Proteins are involved in just about every function in the body as well since enzymes are proteins, and enzymes are the molecules in the body that do much of the work, like building new tissue or removing damaged tissue. Proteins are also message carriers in your body, transporting hormones from one place to another, and transporting signals across your cell membranes to your DNA.

Your body is constantly making new proteins to replenish what's lost from tissue damage or to provide for growth. Enzymes are continually being produced anew to replace older, less functional enzymes. Therefore, to maintain optimal health, your body needs a continuous supply of the nutrients to support protein production.
Proteins are made up of smaller molecules called amino acids that are strung together by chemical bonds like beads on a chain. To become an active, functional protein, this string of amino acids folds in on itself forming a twisted and entwined, three-dimensional structure. An individual protein molecule can be as small as 200 to as large as 5,000 amino acids strung together.

How do I get the protein I need?

In order to make the protein your body needs, it must obtain the protein building blocks, the amino acids, from the proteins in food. Although vegetables and grains do provide some protein, you get most of your protein from nuts, legumes, eggs, fish, meats, and dairy products. When you eat these protein-containing foods, your body must take the large protein chains in them and cut them down to either individual amino acids or dipeptides (two amino acids, di=two, peptide=amino acid) before you can absorb them. Once absorbed, the amino acids are transported through your bloodstream to the tissues that need them, such as muscles. Then, your body uses these amino acids to reconstruct its own proteins in the forms you need to support your tissue's growth and repair.

Your body produces enzymes called proteases to help break down the proteins in food to the amino acids. Proteases cut proteins between specific amino acids to produce the smaller peptide chains. Before the proteases can act on the protein, the protein must first be untwisted, a process called denaturation, which results in a long single-chain protein. Proteins are denatured in the stomach, with the help of the stomach acid (hydrochloric acid), the mixing action of the stomach, and the protease pepsin.

After denaturation in the stomach, the long single-chain protein is transported to the proximal small intestine, the duodenum, which contains several types of proteases. These proteases act on the protein chain, cutting it further until only dipeptides and single amino acids are present. The amino acids and dipeptides are absorbed in the small intestine, primarily in the middle section, the jejunum.

How much protein do I need?

A healthy adult is estimated to need around 40 to 65 grams of protein per day. If this is not provided in the food you eat, your body will begin to break down muscle and other tissues to obtain the amino acids it needs. Inadequate intake and digestion of amino acids from protein can lead to stunting, poor muscle formation, thin and fragile hair, skin lesions, a poorly functioning immune system, and many other symptoms.
In plant and animal foods, the amino acids you need are mainly provided in the form of large protein molecules that require all aspects of protein digestion-denaturation in the stomach and protease action in the intestines-before absorption. Free amino acids, which require no processing by the body before absorption, may also be present but are generally not found in large amounts.

In processed foods, protein is sometimes provided as hydrolyzed protein, which means it has been chemically cut into smaller chains from two to 200 amino acids called peptides. These peptide fragments may be easier for your body to digest; that is, they may not need to be denatured in the stomach, but are still too large for direct absorption and must be digested in the intestine. Some specially produced foods for hospital or healthcare use are made of elemental amino acids; these products provide the amino acids themselves and require no digestion before absorption.

Fats Insulate Your Body's Cells From the Outside World

Fats, also called lipids, are required for many important functions in your body. Fats are a main component of the membranes of all the cells in your body: without fats, your cells would have no covering or boundary. By providing the membrane around all your cells, fats are vital for insulating your body from the outside world. Fats also can be used to provide energy and are involved in supporting the immune system, brain health, and cardiovascular function.

There are many different types of fats, but only a few are essential, which means your body cannot create them internally, so you must take them in through your diet. These essential fats include an omega-6 fatty acid (linoleic acid), and an omega-3 fatty acid (linolenic acid), and are found in the highest amount in nuts, seeds, and fish. Meat contains high levels of fats that are not considered essential, called the saturated fatty acids, and it also contains cholesterol, which is also not essential and is digested in the same way as fats. High amounts of the non-essential saturated fats, and too little of the essential fats can result in problems with the immune system, hardened arteries, and scaling skin, among other symptoms.

As well as being a necessary part of your diet, during digestion, fats also act as carriers of the fat-soluble vitamins (A, D, E, and K) and the carotenoids, thus enabling their absorption. (Carotenoids, such as beta-carotene, are a group of highly colored fat-soluble compounds in plants with a wide range of health protective effects.) Without fats in your diet, you would also not be able to absorb these important vitamins, and would show deficiency symptoms such as problems with blood clotting (vitamin K), weak bones (vitamin D), or vision disturbances (vitamin A).

What happens when I eat a food containing fat?

Fats are present in food primarily as three fat molecules attached to a backbone molecule called glycerol, but your body can't absorb this molecule directly. Like protein, your body must first break down this larger molecule into smaller ones. For example, after you eat a piece of salmon, which contains essential fats, your body must first remove, or strip-off the fat molecules from the glycerol backbone to which they are attached. This process is called hydrolysis, and the types of enzymes that hydrolyze fats from glycerol are called lipases. Lipases are secreted under the tongue, in the stomach, and from the pancreas; therefore, fat hydrolysis begins the minute fats enter your mouth and continues in your stomach, where the majority of fat hydrolysis occurs.

After hydrolysis, the absorption of fats is complicated by the fact that, like any oil, they are insoluble in water, and therefore the body has a system in place to provide a solubilized fat aggregate. The body uses bile acids, which act as detergents, to make fat globules, or aggregates. After aggregation with bile, the fat aggregates, also called miscelles are transported to the small intestine, where they can be taken up directly by the intestinal cells and absorbed into the body.
Absorption of the fat from the miscelles begins in the first part of the small intestine, the duodenum, with the majority of absorption occurring in the mid-section of the intestine, the jejunum. The bile acids generally stay behind in the intestinal tract, acting more as a shuttle.

Carbohydrates Support Your Need for Energy and Provide Fiber for Intestinal Health

Carbohydrates are a varied combination of both very small and very large molecules and comprise about 40 to 45 percent of the energy supply for your body. You get most of your carbohydrates from cereals, fruits and vegetables. Small carbohydrates, like table sugar (sucrose) or glucose, provide a sweet taste to foods. Larger carbohydrates, like starches or fiber, provide substance to foods. Examples of these larger carbohydrates include gums, gels, or pastes, like you get with bread or cookie dough. When cooked, these foods have a structure, like a slice of bread or a cracker, but are mainly composed of different types of carbohydrates.

What happens when I eat a bowl of cereal?

Only the individual small sugar molecules, called monosaccharides (mono=one; saccharide=sugar), can be absorbed directly. Glucose and fructose are examples of monosaccharides. Since carbohydrates exist in food not only as monosaccharides, but also as many combinations of these monosaccharides linked together, your body has to cut these carbohydrates down to their individual monosaccharide units.

Many of the simple sugars that give food its sweet taste are found as two small sugars bonded together. For example, when you eat a bowl of cereal, your body must digest the sucrose (table sugar), which is made of two small sugars, to its monosaccharides. To do this, it uses an enzyme called sucrase, which cuts sucrose to produce glucose and fructose, a process called hydrolysis. The milk on the cereal gets its sweet taste from the carbohydrate called lactose, which is cut (hydrolyzed) into monosaccharides by lactase, to produce galactose and glucose. The majority of carbohydrate hydrolysis occurs in the small intestine; that is, these carbohydrates are mainly transported to the small intestine before they are cut into the monosaccharides glucose, galactose, and fructose. After hydrolysis, these individual monosaccharides are then absorbed directly in the duodenum and jejunum.
Cereals are also high in fiber and provide your body with this important nutrient. Fiber is made of very large carbohydrates containing types of chemical structures that aren't broken down, or digested, by your body. Fiber travels through your gastrointestinal tract intact and ends up in the large intestine, where it provides nutrition for the intestinal bacteria that ferment it. Fiber is called soluble or insoluble, depending on its ability to take up water and to be fermented in the large intestine.

What is starch?


Plants store their energy by stringing together many glucose molecules into a long complex of several hundred to several thousand glucose molecules. Plant foods that have stored energy, for example seeds that must provide energy for the young plant when it starts growing, are high in starch. When the young plant starts growing, the starch is broken down to form glucose for energy. Starch is found in food as amylose starch, which is a straight chain starch, and amylopectin starch, which is a branched chain starch.

When you eat foods with starch, like corn or potatoes, your body digests this very large carbohydrate in much the same way as it digests protein. Your body uses a number of enzymes to cut down a large, linear starch chain into the small individual units that are linked together, the glucose molecules, which can then be absorbed in the intestines. The enzymes that breakdown starches are called amylases. Amylases are very important because starch is prevalent in our diet and a main source from which we derive glucose, the primary sugar molecule the body uses for energy. Amylases actually cut starch down to two-sugar units, maltose and isomaltose, and then other enzymes, called maltase and isomaltase, hydrolyze these two sugars into the individual monosaccharide glucose.

Amylases are produced in the mouth and, therefore, when you eat starch it is immediately acted upon, beginning the process of starch breakdown. This is one of the reasons why thoroughly chewing rather than gulping your food is so important. Since the smaller sugars that come from amylase action on starch are sweeter tasting, if you hold a cracker in your mouth and swish saliva around it, you may notice the appearance of a sweeter taste.

One special kind of starch is found in some foods, such as raw, green bananas. It is called resistant starch, and gets its name because it is resistant to digestion. Therefore, resistant starch is more like a fiber, traveling through the intestinal tract undigested until it reaches the large intestine where, like fiber, it may be fermented by the bacteria in the colon.

Vitamins and Minerals are Absorbed Selectively

Vitamins and minerals are quite varied in structure and amount in the foods you eat. They can be found in food in a free form, chemically bound to a larger molecule, or tightly encased inside a food aggregate. In most cases, they are liberated during eating by the mechanical process of grinding. They may also be liberated during the breakdown of the large molecules like proteins and starch, in which they may be encased.

Since your body requires specific amounts of these key nutrients, most vitamins and some minerals have active transports in place for absorption and are taken into the body in very specific ways. These active transports act as shuttles, picking up the vitamin or mineral and taking it through the intestinal cell wall into the body, where it may be directly released or transferred to another transport molecule. Since vitamins and minerals are small and are usually found in much lower levels than amino acids, carbohydrate, and fats, these active transports must select and pull these important molecules out of the food and take them into your body. Active transports require energy to function properly.

Calcium and iron are examples of minerals that are taken into the body by active transport. Most of the water-soluble vitamins have an active transport in place as well, and these active transports are primarily found in the middle section of the small intestine, the jejunum. Some minerals, like iron and calcium, are absorbed in the first part of the small intestine as well as the jejunum. The fat-soluble vitamins (vitamins A, D, K, and E), as discussed above, are absorbed with fat miscelles, and therefore require fat to be present for their full absorption.

Magnesium is a mineral of tremendous importance for bone health, energy production, and overall healthy functioning throughout the body since it activates more than 300 cellular enzymes. Like calcium, magnesium must be constantly supplied to maintain optimal function. Magnesium doesn't have an active transport, but depends entirely on dietary intake and a healthy intestinal lining for its absorption, and can be absorbed throughout the entire small intestine and even in the colon. Low intakes of magnesium, or loss of ability of the intestinal tract to absorb magnesium due to intestinal inflammation or disease, can result in a variety of problems such as muscle twitching or tremors, weakness, irritability and restlessness, depression, and weak bones. Magnesium is found at highest levels in whole foods such as grains but is often removed during processing. Whole grain bread and cereals will have a much higher amount of magnesium than white bread, which is made from refined flour.
Vitamin B12 is also absorbed differently from the other vitamins and minerals. First, it is most commonly found attached to proteins, and therefore requires protein breakdown to be liberated. Then, it requires a protein made in the stomach, called intrinsic factor, for its absorption, but is not absorbed until the vitamin B12-intrinsic factor complex reaches the final part of the small intestine, the ileum. Optimal digestion of vitamin B12 is dependent on your ability to make a healthy amount of stomach acid, since protein breakdown requires stomach acid and research has shown that intrinsic factor is also not secreted in adequate levels when stomach acid is low.

DIGESTION


Click on eat to start the animation. Run your mouse over the parts of the digestive track to see what they do. <object classid="clsid<img src=" images="" smilies="" laugh.gif="" alt="" title="Laugh" smilieid="162" class="inlineimg" border="0">27CDB6E-AE6D-11cf-96B8-444553540000" codebase="http://download.macromedia.com/pub/shockwave/cabs/flash/swflash.cab#version=5,0,0,0" height="436" width="480">




<embed src="http://www.whfoods.com/digestion.swf" quality="best" scale="noborder" salign="LT" bgcolor="#FFFFFF" type="application/x-shockwave-flash" pluginspage="http://www.macromedia.com/shockwave/download/index.cgi?P1_Prod_Version=ShockwaveFlash" height="436" width="480"> </object> Where does digestion occur?


The whole process of digestion involves many different organs, which are called the digestive system, and include the mouth, esophagus, stomach, small intestines, large intestines, rectum and anus. Other organs are involved in supporting the digestive process as well, but are not technically considered part of the digestive system. These organs are the tongue, the glands in the mouth that produce saliva, the pancreas, liver and gallbladder.

What happens in the mouth?

Digestion begins in the mouth with the chewing of food (mastication). Mastication not only breaks down very large aggregates of food molecules into smaller particles and allows saliva and enzymes to enter inside the larger food complexes, but also sets off a signaling message to the body to start the entire digestive process. Research has shown that the activation of taste receptors in your mouth and the physical process of mastication signal the neural (nervous) system. For example, the taste of food can trigger the stomach lining to produce acid, a process called the cephalic phase of digestion; therefore, your stomach begins to respond to food even before any food leaves your mouth.

Saliva is secreted by the salivary glands in your mouth and moistens the food to improve the chewing and grinding. Saliva also contains some enzymes that begin the breakdown of starches and fats. For example, carbohydrate digestion begins with the salivary enzyme alpha-amylase, and fat digestion begins with the secretion of the enzyme lingual lipase by glands under your tongue.

What happens in the esophagus?

The esophagus, sometimes called the gullet, connects the mouth to the stomach. It delivers the saliva-mixed food from the mouth to the stomach and serves as an air lock between the outside world and the digestive tract. The importance of the esophagus' ability to separate the mouth and stomach can be seen in the condition known as GERD (gastroesophageal reflux disease), in which the esophageal barrier is not effective, so the acid contents of the stomach can escape into the esophagus. Everyone experiences some gastroesophageal reflux, and the esophagus, with the help of another helpful component of saliva, salivary bicarbonate, has the ability to clear any stomach acid that escapes. In many people, however, this reflux occurs more frequently than it should, causing pain and affecting healthy digestion. This situation is called GERD and is one of the most commonly seen conditions in medicine today.

What happens in the stomach?

The esophagus opens into the stomach, which is a large chamber consisting of the fundus, the body and then the antrum. The entire involvement of the stomach in digestion is called the gastric phase of digestion. The stomach is the primary place where proteins are disassembled and broken down into small peptides. Due to its acidic environment, the stomach is also a decontamination chamber for bacteria and other potentially toxic microorganisms that may have entered your gastrointestinal system through your mouth.

The fundus and body of the stomach, which are usually referred to together and constitute the majority of the stomach in size, are where the stomach stores food before it is delivered to the intestine. When the food enters the fundus and body of the stomach, the lining of the fundus (called the gastric fundal mucosa) produces hydrocholoric acid (HCl). This acidic environment is critical for destroying toxins in foods, such as bacteria, as well as for untwisting the complex three-dimensional protein chains, a process called denaturation of the proteins.

The gastric fundus mucosa also secretes the enzyme pepsinogen, which is present in the stomach much of the time but is inactive until the acid is present, when it becomes activated as pepsin. Pepsin acts on the denatured proteins by hydrolyzing, or cutting, the bonds between amino acids in the protein chain, resulting in several smaller chains, or peptides.

Fat hydrolysis is very active in the stomach. The fats have already been exposed to lipase in the saliva, which begins the hydrolysis, but it is the gastric lipase, secreted by the stomach, that is primarily responsible for fat hydrolysis in humans.
The antrum, or lower part of the stomach, is the site for the stomach's grinding action and contains a sensor mechanism, called gastrin, for regulating the level of acid produced in the body of the stomach. The antrum also controls the emptying of food into the intestine through the pyloric sphincter. This way the food can be delivered into the intestine in a controlled manner. Once the food-acid-enzyme mixture leaves the stomach, it is called chyme. The movement of chyme through the pyloric sphincter stimulates the intestine to release the hormones secretin and cholecystokinin, which signal the pancreas to release its contents, the pancreatic juice, inside the lumen (the lining) of the duodenum (the first segment of the small intestine).

What happens in the small intestine?

The small intestine, which is specifically designed to maximize the digestion and absorption process, has an expanded surface area with inner folds, called plicae, villi and microvilli, to increase its surface area and enhance its ability to absorb nutrients. All together, this surface is called the brush border of the small intestine. Some enzymes are present on the surface of the brush border, such as disaccharidases like sucrase, maltase, and lactose, which hydrolyze disugars (sugars composed of two monosaccharides) to their two individual sugar molecules.

The duodenum, the part of the small intestine that is closest to the stomach, is a neutralization chamber in which the chyme from the stomach is mixed with bicarbonate, which appears again, this time in the pancreatic juice. Bicarbonate lessens the chyme's acidity, thus allowing more enzymes to function and furthering the breakdown of macromolecules still present. The pancreatic juice also contains many of the enzymes necessary for digestion of proteins, such as trypsin and chymotrypsin, enzymes that cut proteins and peptides down into one-, two-, and three-amino acid chains; and amylase, an enzyme that continues the hydrolysis of starch.

A few nutrients, like iron and calcium, are taken up most efficiently in the duodenum; however, the jejunum, the middle section of the small intestine, is the place where most nutrients are actively absorbed. The amino acids as well as most vitamins and minerals are absorbed in the jejunum. The process of absorption used by the jejunum is called active absorption since your body uses energy to select the exact nutrients it needs. Protein carriers or channels hook-up to these nutrients and take them through the cell wall of the jejunum and into the portal vein, which carries them to the liver.
Active fat absorption also occurs in the duodenum and the jejunum, and requires that the fat be put into small aggregates that can be transported into your body directly. The body uses bile as a detergent to solubilize the fat. Bile is produced by the liver, stored in the gall bladder, and released into the duodenum and jejunum after a meal. It then can form miscelles, small fat droplets, for fat absorption. This process is particularly important for the absorption of the fat-soluble vitamins (vitamins A, D, E, and K), and for cholesterol absorption.

The majority of starch is also digested in the duodenum and jejunum, the first and second segments of the small intestine. The monosaccharide products of carbohydrate digestion, glucose and galactose, are actively absorbed through the intestine by a process that requires energy. Fructose, another common monosaccharide product of carbohydrate digestion, and also a common sweetener for many processed foods, is absorbed more slowly by a process called facilitated transport. Facilitated transport does not require energy.

The ileum is the final part of the small intestine. The ileum is responsible for completing the digestion of nutrients and for reabsorbing the bile salts that have helped to solubilize (keep in solution), the fats. Although most nutrients are absorbed in the duodenum and jejunum, the first two segments of the small intestine, the ileum is the place where vitamin B12 is selectively absorbed into your body.
At the end of transport through the small intestine, the chyme has been depleted of around 90 percent of its vitamins and minerals and the majority of its other nutrients. In addition, around eight to 10 liters of fluid is also absorbed in the small intestine each day. Complex carbohydrates that resist the enzyme degradation, such as fiber and resistant starch, remain, as do a small amount of other food molecules and nutrients that have escaped the digestion process. For example, about 3-5% of ingested protein normally escapes digestion and continues to the large intestine.

What happens in the large intestine?


The large intestine is not designed for enhancing absorption but is particularly specialized to conserve the sodium and water that escape absorption in the small intestine, although it only transports about one liter of fluid per day. The large intestine is about five feet long, including its final segments, the colon and the rectum.

It is interesting, given that most digestion and absorption occurs prior to the large intestine, that food, which at this point is primarily fiber, will spend more time in your large intestine than anywhere else during digestion. On average, food travels through the stomach in 1/2 to two hours, continues through the small intestine over the next two to six hours, and spends six to 72 hours in your large intestine before final removal by defecation.

One reason food stays longer in the large intestine may be that the large intestine is capable of generating nutrients from food. The food that makes it into the large intestine is primarily fiber, and the large intestine contains an ecosystem of bacteria that can ferment much of this fiber, producing many nutrients necessary for the health of the colon cells. Colonic fermentation also produces a series of short-chain fatty acids, including proprionate, acetate, and butyrate, which are required for healthy colonic cell growth and have many other health promoting functions in your body.

The friendly bacteria that are responsible for the primary amount of healthy colonic fermentation are called the probiotics (pro-life) and include the Bifidobacteria and Lactobaccillus genuses. Along with providing beneficial fermentation products, probiotic bacteria keep pathogenic, or disease-promoting bacteria, from colonizing your colon. Certain fibers in food, called prebiotics, specifically support these probiotic bacteria. Prebiotics include such molecules as inulin and fructooligosaccharides, which are found in chicory and Jerusalem artichoke, and may include some other carbohydrates such as galactooligosaccharides, arabinogalactans, and arabinoxylans, which are found in soy and rice fibers, and in larch tree extracts.
Some fiber isn't fermented, but it is also important because it provides bulk for stool excretion, and can bind toxins and waste products for their removal through the stool. Finally, the rectum and the anus allow for controlled elimination of stool.

What happens in the pancreas?

The pancreas can be thought of as a protein factory. It produces and secretes many of the enzymes necessary for digestion, which include the enzymes that digest protein (trypsin, chymotryosin, carboxypeptidase, and elastase), enzymes that digest fat (lipase and phospholipase), and the enzyme that digests carbohydrate (alpha-amylase). The pancreas releases these enzymes in a pancreatic juice, which is enriched with bicarbonate. The bicarbonate is used to neutralize the acid in chyme. More than a liter of pancreatic juice is released per day in response to signals from eating a meal.

Since your body's tissues are made of protein, the pancreatic enzymes that digest protein have the ability to digest your own tissues. Your body has an intricate protection from self-digestion by these enzymes. The stomach and intestinal tract lining have a mucous layer protecting the tissue from direct digestion by these enzymes. The pancreas uses other mechanisms for protection. Primarily, it produces the enzymes in an inactive form, called zymogens or proenzymes. For example, trypsin is produced as the inactive proenzyme trypsinogen. Trypsinogen is transported to the intestine where it is activated to trypsin by a protease enzyme on the brush border of the intestinal cells. All pancreatic enzymes except lipase and alpha-amylase are secreted as proenzymes, and are therefore inactive within the pancreas.

What happens in the liver?

The liver is one of the most active organs in your body. The liver is the clearinghouse for all nutrient absorption through the gastrointestinal system. The liver reviews the compounds that have been taken in and has the ability to distinguish toxins and other molecules. It has a detoxification system, in which drugs and toxins are chemically converted to molecules that can be eliminated through the kidneys (urine) or the intestine (stool). The liver is also responsible for synthesizing most of the proteins that circulate in your blood, and it produces bile, which is important for the digestion of fats and is used for the excretion of cholesterol and other fat-soluble molecules.
The liver is the major organ involved in maintaining healthy blood sugar (glucose) levels. It monitors your body's glucose needs and provides glucose from digestion, or obtains glucose by breaking down glycogen, the form in which glucose is stored in your liver. The liver has only about a 24-hour supply of glycogen. In prolonged fasting, when glucose is not provided in the diet and glycogen stores have been used, your liver will synthesize glucose from amino acids and other molecules.

The liver is also the primary organ in which fats are metabolized. The liver can make cholesterol and is the primary place where cholesterol is removed from the blood. The liver eliminates cholesterol in the form of bile acids. Every day, your liver secretes about 500 milliliters of bile acids, which are used during digestion to solubilize fats.

What happens in the gallbladder?


The gallbladder is the storage site for the bile acids produced by the liver. After a meal is consumed, the gallbladder is signaled to release its contents into the duodenum and jejunum, where they are available for fat digestion.

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