Chapter 12: Digestive System

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Digestive system

The Mouth• Digestion begins in the mouth.

• Three pairs of salivary glands send saliva (containing salivary amylase for digestion of starch to maltose) into the mouth.

• The tongue mixes the chewed food with saliva and then forms the mixture in preparation for swallowing.

The Pharynx• The air passage (trachea) and food passage (esophagus)

cross in the pharynx. • Swallowing occurs in the pharynx

and is a reflex action. • During swallowing, the air passage

is usually blocked off,

and the trachea moves

under the epiglottis to cover the glottis

opening to the windpipe.

The Esophagus• The esophagus is a muscular tube that

conducts food into the stomach.

• Peristalsis begins in the esophagus; this tube moves the food downward after swallowing.

• No chemical digestion occurs in the esophagus.

• Heartburn is a burning pain when acidic stomach contents enter the esophagus.

The Stomach• The stomach expands to store food.• Food in the stomach is churned, mixing the

food with gastric juices containing hydrochloric acid and pepsin for the digestion of protein to peptides.

• Alcohol, but not food, is absorbed here.• In 2–6 hours, the soupy chyme leaves the

stomach. • Ulcers are usually caused by a bacterial

infection.

The Small Intestine• The small intestine, averaging about 6 meters

in length, is small in diameter.• The first part receives bile from the gallbladder

and pancreatic juice containing pancreatic lipase and trypsin for digestion of protein to peptides, as well as lipase for digestion of fat to glycerol and fatty acids.

• Pancreatic juice contains NaHCO3 that is basic and neutralizes the acid from the stomach.

• Enzymes that finish the process of digestion are produced by the intestinal wall.

• Walls of the small intestine have finger-like projections called villi where nutrient molecules are absorbed into the cardiovascular and lymphatic systems.

• Villi have microvilli that increase the surface area available for absorption.

The Small Intestine

Anatomy of the small intestine

• Peptidases and maltase, produced by the small intestine, complete the digestion of proteins and starches, respectively.

• Glucose and amino acids are absorbed into the blood capillaries of the villi.

• Digestive enzymes speed specific reactions and function best at a warm body temperature and optimum pH.

The Small Intestine

The Large Intestine• The large intestine consists of the cecum, colon,

rectum and anal canal. • The large intestine does not produce digestive

enzymes but does absorb water, salts, and some vitamins.

• Indigestible material is stored in the rectum until the anus allows defecation.

• Water tests that show the presence of the bacterium Escherichia coli indicate water is contaminated.

Three Accessory Organs:1. Pancreas2. Liver3. Gallbladder

The Pancreas• The pancreas produces pancreatic juice,

which contains digestive enzymes for carbohydrate (pancreatic amylase), protein (trypsin), and fat (lipase), along with sodium bicarbonate (NaHCO3) to neutralize acid in chyme.

• The pancreas is also an endocrine gland that secretes insulin and glucagon, hormones that keep blood glucose within normal limits.

The Liver: Gatekeeper• The liver produces bile, which is stored in the

gallbladder. • Bile emulsifies fats; it is a yellowish-green

substance containing bilirubin from hemoglobin breakdown and bile salts derived from cholesterol.

• The liver acts as gatekeeper to the body and receives blood from the small intestine by way of the hepatic portal vein.

Hepatic portal system

The functions of the liver are many:• detoxifies blood,

• stores iron and vitamins, • stores glucose as glycogen,

• produces urea from amino acids, • removes bilirubin after dismantling blood cells, and

• regulates blood cholesterol level when producing bile salts.

The Liver: Gatekeeper

Liver Disorders• When a person has a liver disorder, jaundice

may occur.

• Jaundice is a yellowish tint to eyes and skin, indicating abnormal levels of blood bilirubin.

• Hepatitis is inflammation of the liver; different strains of virus cause hepatitis A, B, C.

(A from sewage, B from sex, blood, needles, and C from blood – vaccines for A and B only)

• Cirrhosis is scar tissue that can form when the liver is diseased or killed by exposure to alcohol.

The Gallbladder• The gallbladder is a pear-shaped muscular

organ that stores bile until it is sent to the small intestine.

• Gallstones are crystals of cholesterol.

Digestion: What’s to eat?!?

Carbohydrates• Complex carbohydrates from foods like breads

and pasta can be converted to glucose and used rapidly.

• Body cells can utilize fatty acids as an energy source, but brain cells require glucose, thus carbohydrates are an essential part of the diet.

• Complex, rather than simple, carbohydrates should make up the bulk of the diet.

• Simple carbohydrates like table sugar (sucrose) contribute to energy needs and weight gain without supplying other nutrients.

• Insoluble fiber helps regularity and may help prevent cancer by limiting the time substances are in contact with the intestinal wall.

• Soluble fiber combines with bile acids and cholesterol in the intestine and prevents them from being absorbed.

Carbohydrates

Proteins• Meat, milk or eggs are complete proteins;

they provide all 20 essential amino acids. • Because individual vegetables do not provide

all essential amino acids, vegetarians must consume a combination of veggies to obtain all proteins.

• The amino acid pool relies on continual uptake; amino acids are not stored.

Lipids : not all bad!• Fat and cholesterol are lipids.

• Lipids, found in fats and oils, should be used sparingly (30% or less of daily calories).

• High-density lipoproteins (HDL- GOOD) carry cholesterol to the liver. Low density lipoprotein (LDL- BAD) takes cholesterol to the cells and may contribute to plaque on blood vessels walls

• Polyunsaturated fats are essential for health!

Fake Fat• Olestra looks, tastes, and acts like real fat but

the digestive system cannot digest it; therefore, it is called “fake fat”.

• However, fat-soluble vitamins are taken up by olestra and pass through the digestive system unabsorbed – you lose nutrition with the “fat”.

• Those who consume olestra have reduced carotenoids in their blood.

Vitamins• Vitamins are organic compounds that the body

cannot produce but needs for metabolic purposes; some are portions of coenzymes.

• Vitamins A, E, and C are antioxidants that protect cell contents from damage due to free radicals.

• Free radicals donate an electron to DNA, proteins, enzymes, membranes, etc. and can damage cell structures or cause cancer.

Vitamin D

• A precursor molecule in skin is converted to vitamin D after exposure to ultraviolet (UV) light.

• Vitamin D is modified first in the kidneys and then the liver until it becomes calcitriol, which is needed for calcium absorption in intestines.

• In the U.S., milk is often fortified by vitamin D.

• Vitamin D is a fat-soluble vitamin.

Illnesses due to vitamin deficiency

Minerals• The body contains both major minerals and

trace minerals.

• Calcium and phosphorus are in bones and teeth.

• Potassium and sodium are involved in nerve conduction.

• Trace minerals are critical in various enzymes and hormones.

Minerals in the body

• Calcium is needed to have strong bones. • Older women in particular are at risk for

osteoporosis, a degenerative bone disease due to insufficient intake of calcium because bone cells are constantly building and eroding bone tissue.

• Calcium supplement with vitamin D (and also estrogen for women) can help prevent this bone loss.

Minerals: Calcium

• Most Americans have too much salt in their diet.

• High sodium intake is linked to hypertension in some persons.

• About one-third of the sodium we consume occurs naturally in foods; another one-third is added during commercial processing; and the final one-third is added during cooking or at the table in the form of table salt.

Minerals : Sodium

Eating Disorders• Obesity is defined as a body weight of more

than 20% above the ideal weight for that person.

• Obesity can have hormonal, metabolic, and social causes.

• For many, a commitment to a sensible diet and exercise program can prevent obesity or a harmful cycle of weight gain-and-loss.

• Bulimia nervosa is characterized by a restrictive diet, binging, and purging.

• Psychotherapy and antidepressants may help.

• Anorexia nervosa is characterized by a distorted body image and feeling fat even when emaciated.

• It can be life-threatening and carries the same risks as starvation.

Eating Disorders

• The mouth, pharynx, esophagus, stomach, small and large intestines have distinct functions and hormones control digestive gland secretions.

• The pancreas, liver, and gallbladder are accessory organs of digestion; their secretions assist digestion.

• The products of digestion are small molecules, such as amino acids and glucose, that can cross plasma membranes.

Digestion Summary

Chapter 16: Excretory System(cleaning your blood)

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

The Urinary System

Functions of the Urinary System• Excretion refers to the elimination of metabolic

wastes that were cell metabolites; this is the function of the urinary system. (This is different than the elimination of digested material: defecation)

• Kidneys play a role in homeostasis of the blood by excreting metabolic wastes, and by maintaining the normal water-salt and acid-base balances of blood.

The Urinary System

• The kidneys produce urine which is conducted by two muscular tubes called ureters to the urinary bladder where it is stored before being released through the urethra.

• Two urethral sphincters control the release of urine.

• In females, the urethra is 4 cm long; in males, the urethra is 20 cm long and conveys both urine and sperm during ejaculation.

The Urinary System

Urination• As the bladder fills with urine, sensory impulses

travel to the spinal cord where motor nerve impulses return and cause the bladder to contract and sphincters to relax.

• With maturation, the brain controls this reflex and delays urination, the release of urine, until a suitable time.

Urination

Functions of the Urinary System1. Excretion of Metabolic Wastes 2. Maintenance of Water-Salt Balance3. Maintenance of Acid-Base Balance4. Secretion of Hormones

1. Excretion of Metabolic WastesKidneys excrete nitrogenous wastes, including

urea, uric acid, and creatinine.a. Urea is a by-product of amino acid metabolism. b. The metabolic breakdown of creatine phosphate

in muscles releases creatinine.c. Uric acid is produced from breakdown of

nucleotides.• Collection of uric acid in joints causes gout.

2. Maintenance of Water-Salt Balance• Kidneys maintain the water-salt balance of the body

which, in turn, regulates blood pressure.

*recall the principles of hyper- and hypo-tonic solutions!*• Salts, such as NaCl, in the blood cause osmosis into

the blood; the more salts, the greater the blood volume and also blood pressure.

• Kidneys also maintain correct levels of potassium, bicarbonate, and calcium ions in blood.

3. Maintenance of Acid-Base Balance• The kidneys regulate the acid-base balance of

the blood.

• Kidneys help keep the blood pH within normal limits by excreting hydrogen ions (H+) and reabsorbing bicarbonate ions (HCO3

-) as needed.

• Urine usually has a pH of 6 or lower because our diet often contains acidic foods.

4. Secretion of HormonesKidneys secrete or activate several hormones:1) They secrete the hormone erythropoietin to

stimulate red blood cell production, 2) They activate vitamin D to the hormone

calcitriol needed for calcium reabsorption during digestion

Gross anatomy of a kidney

• Each nephron has its own blood supply, to more effectively filter large quantities of metabolic waste. Kidneys must filter ALL your blood, ALL the time!

Anatomy of a Nephron

Steps in urine formation

Reabsorption of Water• Salt diffuses out of the lower portion of the

ascending limb of the loop• Water is reabsorbed by osmosis from all parts

of the tubule. • The ascending limb of the nephron establishes

an osmotic gradient that draws water from the descending limb of the nephron and the collecting duct.

Reabsorption of Water• The amount of water absorbed is under the

control of antidiuretic hormone (ADH).

• Diuresis increases water and thus, urine flow and antidiuresis decreases water.

• When ADH is present, more water is reabsorbed, blood volume and blood pressure rise, and there is less urine.

• In the absence of ADH, less water is reabsorbed and therefore there is MORE urine output.

Reabsorption of water

Diuretics Diuretics are chemicals that lower blood pressure

by increasing urine output.

• Alcohol inhibits secretion of ADH; dehydration after drinking may contribute to the effects of a hangover.

• Caffeine increases the glomerular filtration rate and decreases tubular reabsorption of sodium.

• Diuretic drugs inhibit active transport of Na+ so a decrease in water reabsorption follows.

Chapter 13: Cardiovascular System

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

The Blood VesselsThe cardiovascular system has three types of blood

vessels:

1. Arteries (and arterioles) – carry blood away

from the heart

2. Capillaries – where nutrient and gas exchange

occur

3. Veins (and venules) – carry blood toward the

heart.

3 Types of Blood vessels

1. The Arteries• Arteries and arterioles take blood away from

the heart.

• The largest artery is the aorta.

• The middle layer of an artery wall consists of smooth muscle that can constrict to regulate blood flow and blood pressure.

• Arterioles (small arteries) can also constrict or dilate, changing blood pressure.

2. The Capillaries• Capillaries have walls only one cell thick to

allow exchange of gases and nutrients with tissue fluid. (they are tinytinytinytiny!!!!)

• Capillary beds are present in all regions (which is why you bleed everywhere) of the body but not all capillary beds are open at the same time.

Anatomy of a capillary bed

3. The Veins• Venules drain blood from capillaries, then join

to form veins that take blood to the heart. • Veins have much less smooth muscle than

arteries. • Veins often have valves that prevent the

backward flow of blood when closed.

The Heart• The heart is a cone-shaped, muscular

organ located between the lungs behind the sternum.

• The heart muscle forms the myocardium, with tightly interconnect cells of cardiac muscle tissue.

External heart anatomy

Internal view of the heart

• The heart has four chambers: two upper, thin-walled atria, and two lower, thick-walled ventricles.

• The septum is a wall dividing the right and left sides.

• Atrioventricular valves occur between the atria and ventricles – the tricuspid valve on the right and the bicuspid valve on the left

• Semilunar valves occur between the ventricles and the attached arteries

Path of blood through the heart

1

2

3

5

4

6

• The pumping of the heart sends out blood under pressure to the arteries.

• Blood pressure is greatest in the aorta; the wall of the left ventricle is thicker than that of the right ventricle and pumps blood to the entire body.

12 5

4

The Heartbeat• Each heartbeat is called a cardiac cycle.• When the heart beats, the two atria contract

together, then the two ventricles contract; then the whole heart relaxes.

• Systole is the contraction of heart chambers; diastole is their relaxation. (Your blood pressure)

• The heart sounds, lub-dup, are due to the closing of the heart valves (first, atrioventricular valves, followed by the closing of the semilunar valves).

Stages in the cardiac cycle

“Lub”

“Dup”

Intrinsic Control of Heartbeat• The SA (sinoatrial) node, or pacemaker, initiates the

heartbeat and causes the atria to contract on average every 0.85 seconds.

• The AV (atrioventricular) node conveys the stimulus and initiates contraction of the ventricles.

Extrinsic Control of Heartbeat• A cardiac control center in the lower brain

speeds up or slows down the heart rate by way of the autonomic nervous system branches.

• Hormones epinephrine and norepinephrine from the adrenal medulla also stimulate faster heart rate.

Recording your heartbeat:The Electrocardiogram

• An electrocardiogram (ECG) is a recording of the electrical changes that occur in the myocardium during a cardiac cycle.

• Atrial depolarization creates the P wave, ventricle depolarization creates the QRS wave, and repolarization of the ventricles produces the T wave.

• Ventricular fibrillation is uncoordinated contraction of the ventricles. A normal heart-beat can be restored by using a “defibrillator” to RE-SET the AV node current.

Electrocardiogram: ECG

The Vascular PathwaysThe cardiovascular system includes two circuits:

1) Pulmonary circuit which circulates blood through the lungs (getting oxygen into the blood)

2) Systemic circuit which circulates blood to the rest of the body (getting oxygen to the tissues)

3) Both circuits are vital to homeostasis.

Major arteries and veins of the systemic circuit

Coronary artery circulation

• The coronary arteries serve the heart muscle itself; they are the first branch off the aorta.

• Since the coronary arteries are so small, they are easily clogged, leading to heart disease.

• When someone has a heart-attack or coronary, typically, a coronary artery is clogged and the heart tissue is starved, and dies.

Coronary artery circulation

Blood Flow• The beating of the heart is necessary to

homeostasis because it creates pressure that propels blood in arteries and the arterioles.

• Arterioles lead to the capillaries where nutrient and gas exchange with tissue fluid takes place.

Blood Flow in Arteries• Blood pressure due to the pumping of the

heart accounts for the flow of blood in the arteries.

• Systolic pressure is high when the heart expels the blood.

• Diastolic pressure occurs when the heart ventricles are relaxing.

• This pressure is so strong, it can be measured through your skin using the arm-cuff in the doctors office

Blood Flow in Capillaries• Blood moves slowly in capillaries because

there are more capillaries than arterioles and the capillaries are smaller.

• This allows time for substances to be exchanged between the blood and tissues.

Blood Flow in Veins• Venous blood flow is dependent upon:

1) skeletal muscle contraction,

2) presence of valves in veins

3) respiratory movements.

Compression of veins causes blood to move forward past a valve that then prevents it from returning backward. Walking, running, moving, will help push blood through your veins. Varicose veins can result from blood pooling, no movement or broken/weak valves

Blood• Blood separates into two main parts: plasma

(liquid and proteins) and formed elements (blood cells).

• Plasma accounts for 55% and formed elements 45% of blood volume.

• Plasma contains mostly water with some plasma proteins, but it also contains nutrients and wastes.

Composition of blood

Types of Blood Cells

• Red blood cells• White blood cells• Platelets – for clotting (not actual cells, but

pieces of a larger cell)

The Red Blood Cells• Red blood cells (erythrocytes or RBCs) are made

in the red bone marrow of the skull, ribs, vertebrae, and the ends of long bones.

• Red blood cells contain the pigment hemoglobin for oxygen transport; hemogobin contains heme, a complex iron-containing group that transports oxygen in the blood.

(it is the iron that makes your red blood cells, appear red!)

Physiology of red blood cells

• The air pollutant carbon monoxide combines more readily with hemoglobin than does oxygen, resulting in oxygen deprivation and possible death.

• Red blood cells lack a nucleus and have a 120 day life span.

• When worn out, the red blood cells are dismantled in the liver and spleen.

( remember? left over bits and scraps are sent to the liver where they are converted to bili-rubin which colours liver –bile a yellow-green colour and

makes people with jaundice appear yellow!).

Red Blood Cells

• Iron is reused by the red bone marrow where stem cells continually produce more red blood cells

• Lack of enough hemoglobin results in anemia. (not enough hemoglobin=not enough O2 to body = a very, very,

tired person)

• The kidneys produce the hormone erythropoietin to increase blood cell production when oxygen levels are low. (go to a higher elevation….thinner air….more erythropoietin produced….more RBCs…….get stronger,faster! – Also, athletes dope with it….)

Red Blood Cells

The White Blood Cells• White blood cells (leukocytes) have nuclei, are

fewer in number than RBCs, and defend against disease.

• Leukocytes are divided into granular and agranular based on appearance.

• Granular leukocytes (neutrophils, eosinophils, and basophils) contain enzymes and proteins that defend the body against microbes.

• Macrophages that phagocytize microbes and stimulate other cells to defend the body.

• Lymphocytes (B and T cells) are involved in immunity.

• An excessive number of white blood cells may indicate an infection or leukemia; HIV infection drastically reduces the number of lymphocytes.

The White Blood Cells

Macrophage engulfing bacteria

The Platelets and Blood Clotting• Red bone marrow produces large cells called

megakaryocytes that fragment into platelets.

• Clotting factors in the blood help platelets form blood clots.

• The liver plasma proteins involved in the clotting process.

• Trapped red blood cells make a clot appear red.

Blood clotting

Hemophilia: Blood Clot Disorder• Hemophilia is an inherited clotting disorder due

to a deficiency in a clotting factor.

• Bumps and falls cause bleeding in the joints; cartilage degeneration and resorption of bone can follow.

• The most frequent cause of death is bleeding into the brain with accompanying neurological damage.

Where do all these blood cells come from?

Bone Marrow Stem Cells• A stem cell is capable of dividing into new cells

that differentiate into particular cell types.• Bone marrow is multipotent, able to continually

give rise to particular types of blood cells. • The skin and brain also have stem cells, and

mesenchymal stem cells give rise to connective tissues including heart muscle.

Blood cell formation in red bone marrow

Capillary Exchange• At the arteriole end of a capillary, water moves

out of the blood due to the force of blood pressure.

• At the venule end, water moves into the blood due to osmotic pressure of the blood.

• Substances that leave the blood contribute to tissue fluid, the fluid between the body’s cells.

• Excess tissue fluid is returned to the blood stream as lymph in lymphatic vessels.

Lymphatic capillaries

Cardiovascular Disorders• Cardiovascular disease (CVD) is the leading

cause of death in Western countries.

• Modern research efforts have improved diagnosis, treatment, and prevention.

• Major cardiovascular disorders include atherosclerosis, stroke, heart attack, aneurysm, and hypertension.

Atherosclerosis• Atherosclerosis is due to a build-up of fatty

material (plaque), mainly cholesterol, under the inner lining of arteries.

• The plaque can cause a thrombus (blood clot) to form.

• The thrombus can dislodge as an embolus and lead to thromboembolism.

Stroke, Heart Attack, and Aneurysm• A cerebrovascular accident, or stroke, results

when an embolus lodges in a cerebral blood vessel or a cerebral blood vessel bursts; a portion of the brain dies due to lack of oxygen.

• A myocardial infarction, or heart attack, occurs when a portion of heart muscle dies due to lack of oxygen.

• Partial blockage of a coronary artery causes angina pectoris, or chest pain.

• An aneurysm is a ballooning of a blood vessel, usually in the abdominal aorta or arteries leading to the brain.

• Death results if the aneurysm is in a large vessel and the vessel bursts.

• Atherosclerosis and hypertension weaken blood vessels over time, increasing the risk of aneurysm.

Coronary Bypass Operations• A coronary bypass operation involves removing a

segment of another blood vessel and replacing a clogged coronary artery.

• It may be possible to replace

this surgery with gene therapy

that stimulates new blood vessels

to grow where the heart needs

more blood flow.

Clearing Clogged Arteries• Angioplasty uses a long tube threaded through

an arm or leg vessel to the point where the coronary artery is blocked; inflating the tube forces the vessel open.

• Small metal stents are expanded inside the artery to keep it open.

• Stents are coated with heparin to prevent blood clotting and with chemicals to prevent arterial closing.

Angioplasty

Dissolving Blood Clots• Medical treatments for dissolving blood clots

include use of t-PA (tissue plasminogen activator) that converts plasminogen into plasmin, an enzyme that dissolves blood clots, but can cause brain bleeding.

• Aspirin reduces the stickiness of platelets and reduces clot formation and lowers the risk of heart attack.

Heart Transplants and Artificial Hearts• Heart transplants are routinely performed but

immunosuppressive drugs must be taken thereafter.

• There is a shortage of human organ donors.

• Work is currently underway to improve self-contained artificial hearts, and muscle cell transplants may someday be useful.

Hypertension• About 20% of Americans suffer from

hypertension (high blood pressure).

• Hypertension is present when systolic pressure is 140 or greater or diastolic pressure is 90 or greater; diastolic pressure is emphasized when medical treatment is considered.

• A genetic predisposition for hypertension occurs in those who have a gene that codes for angiotensinogen, a powerful vasoconstrictor.

Chapter Summary

• Specialized vessels deliver blood from heart to capillaries, where exchange of substances takes place; another series of vessels delivers blood from capillaries back to heart.

• The human heart is a double pump: the right side pumps blood to the lungs, and the left side pumps blood to the rest of body.

• Pulmonary arteries transport blood low in oxygen to lungs; pulmonary veins return blood high in oxygen to the heart.

• Systemic circulation transports blood from the left ventricle of the heart to the body and then returns it to the right atrium of the heart.

• Blood is composed of cells and a fluid containing proteins and various other molecules and ions.

• Blood clotting is a series of reactions; a clot forms when fibrin threads entrap red blood cells.

• Nutrients pass from blood and tissue fluid across capillary walls to cells; wastes move the opposite direction.

• The cardiovascular system is efficient but it is still subject to degenerative disorders.

Lab Ex 21: Mollusca

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Evolutionary tree

Evolutionary tree

Evolutionary tree

Mollusc Characteristics• A mollusc body typically contains a visceral mass

(soft body mass), a mantle, and a foot.

• Molluscan groups are distinguished by a modification of the foot:

a. In gastropods, the foot is ventrally flattened.(think snails, clams, chitons)

b. In cephalopods, the foot has evolved into

tentacles about the head. (squids, octopi)

Molluscan diversity

Five Classes (all marine!):1. Gastropoda: snails and slugs

2. Polyplacophora: chitons

3. Scaphopoda: “tooth” or “tusk” shells

4. Cephalopoda: octopi, squids, cuttlefish, nautilus

5. Bivalvia: scallops, clams, mussels, oysters, etc..

• Squids are cephalopods that display marked cephalization, move rapidly by jet propulsion, and have a closed circulatory system.

• The camera-type eye.• Shell (except for Nautilus) is reduced or absent.• In cephalopods, the brain is formed from a fusion of

ganglia, and nerves leaving the brain supply the body. (these guys tend to be smart!)

• Rapid secretion from an ink gland helps cephalopods escape enemies.

Cephalopods

Bivalves• Bivalves, such as clams and relatives, have

a hatchet foot and are filter feeders. • Water enters by an incurrent siphon. • Food trapped on the gills is swept toward the

mouth. • A coelom is present but reduced. • The circulatory system pumps blood through

sinuses.

• In bivalves, there is no head and three pairs of ganglia control the bivalve.

• The digestive system of a clam includes a mouth with labial palps, an esophagus, a stomach, and an intestine, which coils about the visceral mass and then is surrounded by the heart as it extends to the anus.

• The anus empties at an excurrent siphon.• Sexes are usually separate and the gonad

is located around the coils of the intestine.

The Clam: more complex than you may have thought!

Ex 22: Annelida (segmented worms)

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Evolutionary tree

Annelids

• Annelids are segmented both externally, and internally by partitions called septa.

• Annelids have a hydrostatic skeleton, and partitioning of the coelom permits each body segment to move independently.

• The tube-within-a-tube body plan allows the digestive tract to have specialized organs.

• Annelids have an extensive closed circulatory system with blood vessels that run the length of the body and branch to every segment.

• The brain is connected to a ventral solid nerve cord with ganglia in each segment.

• The excretory system has nephridia in each segment.

• A nephridium is a tubule that collects wastes and excretes through an opening in the body wall.

Marine Worms

• Polychaetes are marine worms with paddlelike parapodia at the side of each segment.

• Some polychaetes are sessile tube worms.

• A clam worm is a predaceous marine worm with a defined head region.

• During breeding seasons, some worms form sex organs in special segments and shed these segment during breeding.

Polychaete diversity

Earthworms• Earthworms are oligochaetes having few

setae per segment. • Most scavenge for food in the soil and the

moist body wall functions in gas exchange. • When muscles contract in each segment,

setae anchor in the soil, and aid locomotion. • Five “hearts” pump blood and a branch

blood vessel reaches each segment. • These worms are hermaphroditic.

• Segmentation in earthworms is evidenced by:

• Body rings

• Coelom divided by septa

• Setae on most segments

• Ganglia and lateral nerves in each segment

• Nephridia in most segments

• Branch blood vessels in each segment

Earthworm, Lumbricus

Leeches

• Most leeches are fluid feeders that attach themselves to open wounds using suckers.

• Bloodsuckers, such as the medicinal leech, can cut through tissue.

• An anticoagulant (hirudin) in their saliva keeps blood from clotting.