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Chapters 13-16
Levels of Organization in Humans
Human Organ Systems Skeletal System
Muscular System
Circulatory System
Respiratory System
Digestive System
Nervous System
Reproductive System
Endocrine System
Integumentary System
Excretory System
Lymphatic/Immune System
Skeletal System
Structures: Bones, Cartilage, Ligaments, tendons
Functions: Supports the body, protects internal organs, allows movement, stores mineral reserves, provides a site for blood cell formation
homepage.smc.edu/wissmann_paul/bones/Default.htm
The skeleton makes up the general framework of the body. It is composed of 206 named bones of various shapes and sizes. Strong bands of connective tissue called ligaments hold the bones together. Between many of the bones there are pads of firm, smooth, slightly elastic connective tissue called cartilage. The cartilage works to cushion the ends of the bones where they bump together at a joint.
Bones are alive and continue to grow until about age 25. They are hard due to the high concentration of certain minerals such as calcium and phosphorus. All of the minerals, which the body needs for bone growth or repair, are found in food.
bcms.leesummit.k12.mo.us/sreece/bonyben.htm
Human Joints The joint is the place where two bones meet. There are two types of joints:
immovable joints and movable joints.
Immovable joints do not permit any movement of the bones.
The suture joints of the skull and the fused bones of the sacrum and coccyx are examples of this type of joint.
Movable joints allow the body to move depending on the type of joint will determine how the joint will move.
Movable Joints Hinge joints
found in knee and elbow permit back and forth motion in only one direction.
ball-and-socket joints The hip and shoulder joints They permit nearly a full range of motion.
pivot joint The joint at the base of the skull It allows movement of the head in a circular motion.
gliding joints The joints of the wrist and ankle. The many small bones found in the wrist and ankle move
slightly over one another permitting movement to occur.
ASIMO = Advanced Steps In Mobility
http://asimo.honda.com/default.aspx
Muscular System
Structures: Skeletal Muscle, smooth muscle, cardiac muscle
Function: Works with skeletal system to produce voluntary movement, helps to circulate blood and move food through the digestive system
http://trc.ucdavis.edu/biosci10v/bis10v/week10/08muscularsystem.html
homepage.smc.edu/.../anatomy1/1muscles.html
Circulatory System
Structures: heart, blood vessels, blood
Function: Brings oxygen, nutrients, and hormones to cells, fights infections, removes cell wastes, helps to regulate body temperature
Blood Flow through the Heart
1. Oxygen-poor blood (shown in blue) flows from the body into the right atrium.
2. Blood flows through the right atrium into the right ventricle.
3. The right ventricle pumps the blood to the lungs, where the blood releases waste gases and picks up oxygen.
4. The newly oxygen-rich blood (shown in red) returns to the heart and enters the left atrium.
5. Blood flows through the left atrium into the left ventricle.
6. The left ventricle pumps the oxygen-rich blood to all parts of the body.
www.pbs.org/wgbh/nova/eheart/human.html
Respiratory System
Structures: Nose, pharynx, larynx, trachea, bronchi, bronchioles, lungs
Function: Provides oxygen needed for cellular respiration and removes excess carbon dioxide from the body
One of the main jobs of the cardiovascular system is to deliver oxygen (O2) to the body.
As our bodies work, it uses up oxygen, replacing it with carbon dioxide (CO2).
The exchange of oxygen and carbon dioxide occurs in our lungs. The blood that reaches our lungs has a lot more CO2 than O2. But the air in our lungs normally has a lot more O2 than CO2. Because of this large difference, blood naturally drops of CO2 in our lungs, and picks up O2.
How does this happen? It happens because the pressure of O2
in our capillaries as it travels through our lungs is lower than the pressure of O2 in our lungs.
Since high pressure gases want to travel into areas of low pressure, O2 naturally moves from our lungs into our blood.
The reverse is true for CO2.
The pressure of CO2 in our capillaries is higher than the pressure of CO2 in our lungs, so CO2 naturally travels from our blood and into our lungs.
This gas exchange occurs in sacs called alveoli.
The lung is made of two large sacks, which is divided and folded into much smaller pouches and sacs.
Each sac is connected to a tube called bronchi.
The bronchi are connected to our mouth through another tube called the trachea.
As we breath, air enters our nose and mouth, travels down the trachea, and into the lungs through the bronchi.
Just like our arteries, the bronchi further divide into smaller tubes called bronchioles.
The bronchioles end in the alveoli. Alveoli are surrounded by capillaries, so
the exchange of gases occur through very thin wall vessels.
Air enters our lungs through pressure changes. When we inhale, the muscles on our ribs and our diaphragm contract, expanding our chest. When our chest expands, the air pressure in our lungs drop, pulling air into our lungs. When we relax our muscles, elastic cartilage pulls our ribs in, pushing the air out of our lungs.
http://www.starsandseas.com/SAS%20Physiology/Cardiovascular/Cardiovascular.htm
Digestive System
Structures: Mouth, pharynx, esophagus, stomach, small and large intestines, rectum
Functions: Converts food into simpler molecules that can be used by the cells of the body, absorbs food, eliminates wastes
Nervous System
Structures: Brain, spinal cord. Peripheral nerves
Functions: Recognizes and coordinates the body’s responses to changes in its internal and external environments
Reproductive Systems Structures:
Males-Testes, epididymis, vas deferens, urethra, and penis
Females-Ovaries, Fallopian tubes uterus, vagina
Functions: Produces reproductive cells Males-spermFemales- eggs, also nurtures and protects
developing embryo ○ Stages development
Sperm & egg unite during fertilization to create a zygote- blastocyst – embryo- fetus- Infant
Endocrine System
Structures: Glands- Hypothalamus, pituitary, pineal, thyroid, parathyroid, adrenals, pancreas, ovaries (females), testes (males)
Function: Controls growth, development, and metabolism, maintains homeostasis
Male on left and female on right
1. Pineal gland,
2. Pituitary gland,
3. Thyroid gland,
4. Thymus,
5. Adrenal gland,
6. Pancreas,
7. Ovary, female only
8.Testis, male only
Integumentary System
Structures: Skin, hair, nails, sweat and oil glands
Functions: Serves as a barrier to regulate body temperatures, provides protection against ultraviolet radiation from the sun
Excretory System
Structures: Skin, Lungs, kidneys, ureters, urinary, bladder, urethra
Functions: Eliminates waste products from the body in ways that maintain homeostasis
Lymphatic/immune System Structures: White blood cells, thymus,
spleen lymph nodes, lymph vessels
Functions: Helps protect the body from disease. Collects fluid lost from blood vessels and returns the fluid to the circulatory system
The lymphatic systemThe lymphatic system is part of the immune system, which defends the body against infection. The lymphatic system is a network of small lymph nodes connected by very thin lymph vessels, which branch into every part of the body except the brain and spinal cord.
The major nodes can be found in the neck, armpits, chest, abdomen, pelvis and groin. Other parts of the lymphatic system include the spleen, thymus and bone marrow.
A clear fluid called lymph flows through the lymph vessels. It contains white blood cells called lymphocytes, special proteins called antibodies, and some waste products. Lymphocytes and antibodies are important parts of your body's immune system.
The lymph fluid passes through the lymph nodes, which filter out bacteria and other harmful things
