Transcript Document
The Animal Body and Principles of Regulation Chapter 43 Organization of Vertebrate Body • There are four levels of organization: 1. 2. 3. 4. Cells Tissues Organs Organ systems 2 Organization of Vertebrate Body • Tissues are groups of cells that are similar in structure and function • The three fundamental embryonic tissues are called germ layers – Endoderm, mesoderm and ectoderm • In adult vertebrates, there are four primary tissues – Epithelial, connective, muscle and nerve 3 Organization of Vertebrate Body • Organs are combinations of different tissues that form a structural and functional unit • Organ systems are groups of organs that cooperate to perform the major activities of the body – The vertebrate body contains 11 principal organ systems 4 examples Organization of Vertebrate Body 5 Organization of Vertebrate Body • The body plan of all vertebrates is essentially a tube within a tube – Inner tube - Digestive tract – Outer tube - Main vertebrate body • Supported by a skeleton – Outermost layer - Skin and its accessories • Inside the body are two identifiable cavities 6 Organization of Vertebrate Body 1. Dorsal body cavity - Within skull and vertebrae 2. Ventral body cavity - Bounded by the rib cage and vertebral column and divided by the diaphragm into: – Thoracic cavity - heart and lungs • • Pericardial cavity: around the heart Pleural cavity: around the lungs – Abdominopelvic cavity - most organs • Peritoneal cavity - coelomic space around organs 7 Organization of Vertebrate Body 8 Organization of Vertebrate Body 9 Organization of Vertebrate Body 10 Organization of Vertebrate Body 11 1. Epithelial Tissue • An epithelial membrane, or epithelium, covers every surface of the vertebrate body – Can come from any of the 3 germ layers – Some epithelia change into glands • Cells of epithelia are tightly bound together – Provide a protective barrier • Epithelia possess remarkable regenerative powers replacing cells throughout life 12 1. Epithelial Tissue • Epithelial tissues attach to underlying connective tissues by a fibrous membrane – Basal surface - Secured side – Apical surface - Free side • Therefore, epithelia have inherent polarity, which is important for their function 13 1. Epithelial Tissue • Two general classes – Simple - one layer thick – Stratified - several layers thick • Subdivided by shape into: – Squamous cells - flat – Cuboidal cells - cube-shaped – Columnar cells - cylinder-shaped 14 Simple Epithelium • Simple squamous epithelium – Lines lungs and blood capillaries • Simple cuboidal epithelium – Lines kidney tubules and several glands • Simple columnar epithelium – Lines airways of respiratory tract and most of the gastrointestinal tract – Contains goblet cells that secrete mucus 15 Simple Epithelium • Glands of vertebrates form from invaginated epithelia • Exocrine glands – connected to epithelium by a duct – e.g. sweat, sebaceous and salivary glands • Endocrine glands – ductless – secretions (=hormones) enter blood 16 Stratified Epithelium • Named according to the features of their apical (free side) cell layers – Epidermis is a stratified squamous epithelium • Characterized as a keratinized epithelium • Contains water-resistant keratin • Note: Lips are covered with nonkeratinized, stratified squamous epithelium 17 2. Connective Tissues • Derive from embryonic mesoderm • Divided into two major classes – Connective tissue proper – Loose or dense – Special connective tissue • Cartilage, bone and blood • All have abundant extracellular material called the matrix – Protein fibers plus ground substance • Ground substance is fluid material containing an array of proteins and polysaccharides 18 Connective Tissue Proper • Fibroblasts produce and secrete extracellular matrix • Loose connective tissue – Cells scattered within a matrix that contains large amounts of ground substance – Strengthened by protein fibers such as: • Collagen – Supports tissue • Elastin – Makes tissue elastic 19 Connective Tissue Proper • Adipose cells (fat cells) also occur in loose connective tissue – Develop in large groups in certain areas, forming adipose tissue 20 Connective Tissue Proper • Dense connective tissue – Contains less ground substance and more collagen than loose connective tissue • Dense regular connective tissue – Collagen fibers line up in parallel – Makes up tendons and ligaments • Dense irregular connective tissue: – Collagen fibers have different orientations – Covers kidney, muscles, nerves & bone 21 Special Connective Tissue • Cartilage – Ground substance made from characteristic glycoprotein, called chondroitin, and collagen fibers in long, parallel arrays – Flexible with great tensile strength – Found in joint surfaces and other locations – Chondrocytes (cartilage cells) live within lacunae (spaces) in the ground substance 22 Special Connective Tissue • Bone – Osteocytes (bone cells) remain alive in a matrix hardened with calcium phosphate • Blood – Extracellular material is the fluid plasma – Erythrocytes - red blood cells – Leukocytes - white blood cells – Thrombocytes - platelets 23 3. Muscle Tissue • Muscles are the motors of vertebrate bodies – Three kinds: smooth, skeletal and cardiac – Skeletal and cardiac muscles are also known as striated muscles – Skeletal muscle is under voluntary control, whereas contraction of smooth and cardiac is involuntary 24 3. Muscle Tissue • Smooth muscles are found in walls of blood vessels and visceral organs – Cells are mono-nucleated • Skeletal muscles are usually attached to bone by tendons, so muscle contraction causes bones to move – Muscle fibers (cells) are multi-nucleated • Contract by means of myofibrils, that contain ordered actin and myosin filaments 25 3. Muscle Tissue • Cardiac muscle is composed of smaller, interconnected cells – Each cell has a single nucleus – Interconnections appear as dark lines called intercalated disks – Enable cardiac muscle cells to form a single functioning unit 26 4. Nerve Tissue • Cells include neurons and their supporting cells called neuroglia • Most neurons consist of three parts – Cell body: contains the nucleus – Dendrites: highly branched extensions • conduct electrical impulses toward the cell body – Axon: single cytoplasmic extension • Conducts impulses away from cell body 27 4. Nerve Tissue • Neuroglia do not conduct electrical impulses – Support and insulate neurons and eliminate foreign materials in and around neurons • Associate with axon to form an insulating cover called the myelin sheath – Gaps, known as nodes of Ranvier, are involved in acceleration of impulses 28 4. Nerve Tissue • Nervous system is divided into: – Central nervous system (CNS) • Brain and spinal cord • Integration and interpretation of input – Peripheral nervous system (PNS) • Nerves and ganglia (collections of cell bodies) • Communication of signal to body 29 Overview of Organ Systems • Communication and integration – Three organ systems detect external stimuli and coordinate the body’s responses – Nervous, sensory and endocrine systems 30 Overview of Organ Systems • Support and movement – The musculoskeletal system consists of the interrelated skeletal and muscular organ systems 31 Overview of Organ Systems • Regulation and maintenance – Four organ systems regulate and maintain the body’s chemistry • Digestive, circulatory, respiratory and urinary systems 32 Overview of Organ Systems • Defense – The body defends itself with two organ systems: integumentary and immune 33 Overview of Organ Systems • Reproduction and development – The biological continuity of vertebrates is the province of the reproductive system – In females, the system also nurtures the developing embryo and fetus 34 Homeostasis • As animals have evolved, specialization of body structures has increased • For cells to function efficiently and interact properly, internal body conditions must be relatively constant • The dynamic constancy of the internal environment is called homeostasis • It is essential for life 35 Homeostasis 36 Homeostasis • To maintain internal constancy, the vertebrate body uses negative feedback mechanisms – Changing conditions are detected by sensors (cells or membrane receptors) – Information is fed to an integrating center, also called comparator (brain, spinal cord or endocrine gland) – Compares conditions to a set point 37 Homeostasis • If a deviation is detected, a message is sent to an effector (muscle or gland) – Increase or decrease in activity brings internal conditions back to set point – Negative feedback to the sensor terminates the response 38 Homeostasis 39 Homeostasis • Humans have set points for body temperature, blood glucose concentrations, electrolyte (ion) concentration, tendon tension, etc. • We are endothermic: can maintain a relatively constant body temperature (37oC or 98.6oF) – Changes in body temperature are detected by the hypothalamus in the brain 40 Homeostasis • Negative feedback mechanisms often oppose each other to produce finer degree of control – Many internal factors are controlled by antagonistic effectors • Have “push-pull” action • Increasing activity of one effector is accompanied by decrease in the other 41 Homeostasis • Antagonistic effectors are involved in the control of body temperature – If hypothalamus detects high temperature • Promotes heat dissipation via sweating, and dilation of blood vessels in skin – If hypothalamus detects low temperature • Promotes heat conservation via shivering and constriction of blood vessels in skin 42 Homeostasis room body 43 Homeostasis • In a few cases, the body uses positive feedback mechanisms to enhance a change – These do not in themselves maintain homeostasis – However, they are generally part of some larger mechanism that does! – Examples: • Blood clotting • Contraction of uterus during childbirth 44 Homeostasis 45