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PowerPoint® Lecture Slides prepared by Barbara Heard, Atlantic Cape Community College CHAPTER 1 The Human Body: An Orientation: Part A © Annie Leibovitz/Contact Press Images © 2013 Pearson Education, Inc. Overview of Anatomy and Physiology • Anatomy – Study of structure • Subdivisions: – Gross or macroscopic (e.g., regional, systemic, and surface anatomy) – Microscopic (e.g., cytology and histology) – Developmental (e.g., embryology) © 2013 Pearson Education, Inc. Overview of Anatomy and Physiology • To study anatomy – Mastery of anatomical terminology – Observation – Manipulation – Palpation – Auscultation © 2013 Pearson Education, Inc. Overview of Anatomy and Physiology • Physiology – Study of the function of the body – Subdivisions based on organ systems (e.g., renal or cardiovascular physiology) – Often focuses on cellular and molecular level • Body's abilities depend on chemical reactions in individual cells © 2013 Pearson Education, Inc. Overview of Anatomy and Physiology • To study physiology – Ability to focus at many levels (from systemic to cellular and molecular) – Study of basic physical principles (e.g., electrical currents, pressure, and movement) – Study of basic chemical principles © 2013 Pearson Education, Inc. Principle of Complementarity • Anatomy and physiology are inseparable – Function always reflects structure – What a structure can do depends on its specific form © 2013 Pearson Education, Inc. Levels of Structural Organization • Chemical – Atoms and molecules (chapter 2); and organelles (chapter 3) • Cellular – Cells (chapter 3) • Tissue – Groups of similar cells (chapter 4) • Organ – Contains two or more types of tissues • Organ System – Organs that work closely together • Organismal – All organ systems © 2013 Pearson Education, Inc. Figure 1.1 Levels of structural organization. Atoms Slide 1 Organelle Smooth muscle cell Molecule Chemical level Atoms combine to form molecules. Cellular level Cells are made up of molecules. Cardiovascular system Heart Blood vessels Smooth muscle tissue Tissue level Tissues consist of similar types of cells. Blood vessel (organ) Smooth muscle tissue Connective tissue Epithelial tissue Organ level Organs are made up of different types of tissues. Organ system level Organismal level The human organism is made Organ systems consist of different organs that work together closely. up of many organ systems. © 2013 Pearson Education, Inc. Figure 1.1 Levels of structural organization. Atoms Molecule Chemical level Atoms combine to form molecules. © 2013 Pearson Education, Inc. Slide 2 Figure 1.1 Levels of structural organization. Atoms Molecule Chemical level Atoms combine to form molecules. © 2013 Pearson Education, Inc. Slide 3 Organelle Smooth muscle cell Cellular level Cells are made up of molecules. Figure 1.1 Levels of structural organization. Atoms Molecule Chemical level Atoms combine to form molecules. Slide 4 Organelle Smooth muscle cell Cellular level Cells are made up of molecules. Smooth muscle tissue Tissue level Tissues consist of similar types of cells. © 2013 Pearson Education, Inc. Figure 1.1 Levels of structural organization. Atoms Molecule Chemical level Atoms combine to form molecules. Slide 5 Organelle Smooth muscle cell Cellular level Cells are made up of molecules. Smooth muscle tissue Tissue level Tissues consist of similar types of cells. Blood vessel (organ) Smooth muscle tissue Connective tissue Epithelial tissue Organ level Organs are made up of different types of tissues. © 2013 Pearson Education, Inc. Figure 1.1 Levels of structural organization. Atoms Slide 6 Organelle Smooth muscle cell Molecule Chemical level Atoms combine to form molecules. Cellular level Cells are made up of molecules. Cardiovascular system Heart Blood vessels Smooth muscle tissue Tissue level Tissues consist of similar types of cells. Blood vessel (organ) Smooth muscle tissue Connective tissue Epithelial tissue Organ level Organs are made up of different types of tissues. Organ system level Organ systems consist of different organs that work together closely. © 2013 Pearson Education, Inc. Figure 1.1 Levels of structural organization. Atoms Slide 7 Organelle Smooth muscle cell Molecule Chemical level Atoms combine to form molecules. Cellular level Cells are made up of molecules. Cardiovascular system Heart Blood vessels Smooth muscle tissue Tissue level Tissues consist of similar types of cells. Blood vessel (organ) Smooth muscle tissue Connective tissue Epithelial tissue Organ level Organs are made up of different types of tissues. Organ system level Organismal level The human organism is made Organ systems consist of different organs that work together closely. up of many organ systems. © 2013 Pearson Education, Inc. • What are the bodily functions that MUST occur in order to maintain life? © 2013 Pearson Education, Inc. Necessary Life Functions • • • • • • • • Maintaining boundaries Movement Responsiveness Digestion Metabolism Dispose of wastes Reproduction Growth © 2013 Pearson Education, Inc. Necessary Life Functions • Maintaining boundaries between internal and external environments – Plasma membranes – Skin • Movement (contractility) – Of body parts (skeletal muscle) – Of substances (cardiac and smooth muscle) © 2013 Pearson Education, Inc. Necessary Life Functions • Responsiveness – Ability to sense and respond to stimuli – Withdrawal reflex – Control of breathing rate • Digestion – Breakdown of ingested foodstuffs – Absorption of simple molecules into blood © 2013 Pearson Education, Inc. Necessary Life Functions • Metabolism – All chemical reactions that occur in body cells – Catabolism and anabolism • Excretion – Removal of wastes from metabolism and digestion – Urea, carbon dioxide, feces © 2013 Pearson Education, Inc. Necessary Life Functions • Reproduction – Cellular division for growth or repair – Production of offspring • Growth – Increase in size of a body part or of organism © 2013 Pearson Education, Inc. Interdependence of Body Cells • Humans are multicellular – To function, must keep individual cells alive – All cells depend on organ systems to meet their survival needs • All body functions spread among different organ systems • Organ systems cooperate to maintain life – Note major organs and functions of the 11 organ systems (fig. 1.3) © 2013 Pearson Education, Inc. Figure 1.2 Examples of interrelationships among body organ systems. Digestive system Respiratory system Takes in oxygen and eliminates carbon dioxide Takes in nutrients, breaks them down, and eliminates unabsorbed matter (feces) O2 Food CO2 Cardiovascular system Via the blood, distributes oxygen and nutrients to all body cells and delivers wastes and carbon dioxide to disposal organs Blood CO2 O2 Heart Nutrients Interstitial fluid Urinary system Eliminates nitrogenous wastes and excess ions Nutrients and wastes pass between blood and cells via the interstitial fluid Feces © 2013 Pearson Education, Inc. Integumentary system Protects the body as a whole from the external environment Urine Figure 1.3a The body’s organ systems and their major functions. Hair Skin Nails Integumentary System Forms the external body covering, and protects deeper tissues from injury. Synthesizes vitamin D, and houses cutaneous (pain, pressure, etc.) receptors and sweat and oil glands. © 2013 Pearson Education, Inc. Figure 1.3b The body’s organ systems and their major functions. Bones Joint Skeletal System Protects and supports body organs, and provides a framework the muscles use to cause movement. Blood cells are formed within bones. Bones store minerals. © 2013 Pearson Education, Inc. Figure 1.3c The body’s organ systems and their major functions. Skeletal muscles (c) Muscular System Allows manipulation of the environment, locomotion, and facial expression. Maintains posture, and produces heat. © 2013 Pearson Education, Inc. Figure 1.3d The body’s organ systems and their major functions. Brain Spinal cord Nerves Nervous System As the fast-acting control system of the body, it responds to internal and external changes by activating appropriate muscles and glands. © 2013 Pearson Education, Inc. Figure 1.3e The body’s organ systems and their major functions. Pineal gland Pituitary gland Thyroid gland Thymus Adrenal gland Pancreas Testis Ovary Endocrine System Glands secrete hormones that regulate processes such as growth, reproduction, and nutrient use (metabolism) by body cells. © 2013 Pearson Education, Inc. Figure 1.3f The body’s organ systems and their major functions. Heart Blood vessels Cardiovascular System Blood vessels transport blood, which carries oxygen, carbon dioxide, nutrients, wastes, etc. The heart pumps blood. © 2013 Pearson Education, Inc. Figure 1.3g The body’s organ systems and their major functions. Red bone marrow Thymus Lymphatic vessels Thoracic duct Spleen Lymph nodes Lymphatic System/Immunity Picks up fluid leaked from blood vessels and returns it to blood. Disposes of debris in the lymphatic stream. Houses white blood cells (lymphocytes) involved in immunity. The immune response mounts the attack against foreign substances within the body. © 2013 Pearson Education, Inc. Figure 1.3h The body’s organ systems and their major functions. Nasal cavity Pharynx Larynx Bronchus Trachea Lung Respiratory System Keeps blood constantly supplied with oxygen and removes carbon dioxide. The gaseous exchanges occur through the walls of the air sacs of the lungs. © 2013 Pearson Education, Inc. Figure 1.3i The body’s organ systems and their major functions. Oral cavity Esophagus Liver Stomach Small Intestine Large Intestine Rectum Anus Digestive System Breaks down food into absorbable units that enter the blood for distribution to body cells. Indigestible foodstuffs are eliminated as feces. © 2013 Pearson Education, Inc. Figure 1.3j The body’s organ systems and their major functions. Kidney Ureter Urinary bladder Urethra Urinary System Eliminates nitrogenous wastes from the body. Regulates water, electrolyte and acid-base balance of the blood. © 2013 Pearson Education, Inc. Figure 1.3k–l The body’s organ systems and their major functions. Mammary glands (in breasts) Prostate gland Ovary Penis Testis Scrotum Ductus deferens Uterus Vagina Male Reproductive System Overall function is production of offspring. Testes produce sperm and male sex hormone, and male ducts and glands aid in delivery of sperm to the female reproductive tract. Ovaries produce eggs and female sex hormones. The remaining female structures serve as sites for fertilization and development of the fetus. Mammary glands of female breasts produce milk to nourish the newborn. © 2013 Pearson Education, Inc. Uterine tube Female Reproductive System Overall function is production of offspring. Testes produce sperm and male sex hormone, and male ducts and glands aid in delivery of sperm to the female reproductive tract. Ovaries produce eggs and female sex hormones. The remaining female structures serve as sites for fertilization and development of the fetus. Mammary glands of female breasts produce milk to nourish the newborn. Survival Needs • Appropriate amounts necessary for life – Too little or too much harmful • • • • • Nutrients Oxygen Water Normal body temperature Appropriate atmospheric pressure © 2013 Pearson Education, Inc. Survival Needs • Nutrients – Chemicals for energy and cell building – Carbohydrates, fats, proteins, minerals, vitamins • Oxygen – Essential for energy release (ATP production) © 2013 Pearson Education, Inc. Survival Needs • Water – Most abundant chemical in body – Environment of chemical reactions – Fluid base for secretions and excretions • Normal body temperature – 37° C – Affects rate of chemical reactions • Appropriate atmospheric pressure – For adequate breathing and gas exchange in lungs © 2013 Pearson Education, Inc. Homeostasis • Homeostasis – Maintenance of relatively stable internal conditions despite continuous changes in environment – A dynamic state of equilibrium – Maintained by contributions of all organ systems © 2013 Pearson Education, Inc. Homeostatic Control Mechanisms • Involve continuous monitoring and regulation of all factors that can change (variables) • Communication necessary for monitoring and regulation – Functions of nervous and endocrine systems • Nervous and endocrine systems accomplish communication via nerve impulses and hormones © 2013 Pearson Education, Inc. Components of a Control Mechanism • Receptor (sensor) – Monitors environment – Responds to stimuli (something that causes changes in controlled variables) • Control center – Determines set point at which variable is maintained – Receives input from receptor – Determines appropriate response • Effector – Receives output from control center – Provides the means to respond – Response either reduces (negative feedback) or enhances stimulus (positive feedback) © 2013 Pearson Education, Inc. Figure 1.4 Interactions among the elements of a homeostatic control system maintain stable internal conditions. 3 Input: Information sent along afferent pathway to control center. 2 Receptor detects change. 1 Stimulus produces change in variable. © 2013 Pearson Education, Inc. Receptor Control Center Afferent pathway Efferent pathway BALANCE Slide 1 4 Output: Information sent along efferent pathway to effector. Effector 5 Response of effector feeds back to reduce the effect of stimulus and returns variable to homeostatic level. Figure 1.4 Interactions among the elements of a homeostatic control system maintain stable internal conditions. 1 Stimulus produces change in variable. © 2013 Pearson Education, Inc. BALANCE Slide 2 Figure 1.4 Interactions among the elements of a homeostatic control system maintain stable internal conditions. 2 Receptor detects change. 1 Stimulus produces change in variable. © 2013 Pearson Education, Inc. Receptor BALANCE Slide 3 Figure 1.4 Interactions among the elements of a homeostatic control system maintain stable internal conditions. 3 Input: Information sent along afferent pathway to control center. 2 Receptor detects change. 1 Stimulus produces change in variable. © 2013 Pearson Education, Inc. Receptor Control Center Afferent pathway BALANCE Slide 4 Figure 1.4 Interactions among the elements of a homeostatic control system maintain stable internal conditions. 3 Input: Information sent along afferent pathway to control center. 2 Receptor detects change. 1 Stimulus produces change in variable. © 2013 Pearson Education, Inc. Receptor Control Center Afferent pathway Efferent pathway BALANCE Slide 5 4 Output: Information sent along efferent pathway to effector. Effector Figure 1.4 Interactions among the elements of a homeostatic control system maintain stable internal conditions. 3 Input: Information sent along afferent pathway to control center. 2 Receptor detects change. 1 Stimulus produces change in variable. © 2013 Pearson Education, Inc. Receptor Control Center Afferent pathway Efferent pathway BALANCE Slide 6 4 Output: Information sent along efferent pathway to effector. Effector 5 Response of effector feeds back to reduce the effect of stimulus and returns variable to homeostatic level. Negative Feedback • Most feedback mechanisms in body • Response reduces or shuts off original stimulus – Variable changes in opposite direction of initial change • Examples – Regulation of body temperature (a nervous system mechanism) – Regulation of blood glucose by insulin (an endocrine system mechanism) © 2013 Pearson Education, Inc. Figure 1.5 Body temperature is regulated by a negative feedback mechanism. Control Center (thermoregulatory center in brain) Afferent pathway Efferent pathway Receptors Effectors Sweet glands Temperature-sensitive cells in skin and brain) Sweat glands activated Response Evaporation of sweat Body temperature falls; stimulus ends Body temperature rises BALANCE Stimulus: Heat Stimulus: Cold Response Body temperature falls Body temperature rises; stimulus ends Receptors Temperature-sensitive cells in skin and brain Effectors Skeletal muscles Shivering begins Efferent pathway Afferent pathway Control Center (thermoregulatory center in brain) © 2013 Pearson Education, Inc. Negative Feedback: Regulation of Blood Glucose by Insulin • Receptors sense increased blood glucose (blood sugar) • Pancreas (control center) secretes insulin into the blood • Insulin causes body cells (effectors) to absorb more glucose, which decreases blood glucose levels © 2013 Pearson Education, Inc. Positive Feedback • Response enhances or exaggerates original stimulus • May exhibit a cascade or amplifying effect • Usually controls infrequent events that do not require continuous adjustment – Enhancement of labor contractions by oxytocin (chapter 28) – Platelet plug formation and blood clotting © 2013 Pearson Education, Inc. Figure 1.6 A positive feedback mechanism regulates formation of a platelet plug. 1 Break or tear occurs in blood vessel wall. Positive feedback cycle is initiated. 3 Released chemicals attract more platelets. 2 Platelets Positive feedback loop adhere to site and release chemicals. Feedback cycle ends when plug is formed. 4 Platelet plug is fully formed. © 2013 Pearson Education, Inc. Slide 1 Figure 1.6 A positive feedback mechanism regulates formation of a platelet plug. 1 Break or tear occurs in blood vessel wall. Positive feedback cycle is initiated. © 2013 Pearson Education, Inc. Slide 2 Figure 1.6 A positive feedback mechanism regulates formation of a platelet plug. 1 Break or tear occurs in blood vessel wall. Positive feedback cycle is initiated. 2 Platelets adhere to site and release chemicals. © 2013 Pearson Education, Inc. Slide 3 Figure 1.6 A positive feedback mechanism regulates formation of a platelet plug. 1 Break or tear occurs in blood vessel wall. Positive feedback cycle is initiated. 3 Released chemicals attract more platelets. © 2013 Pearson Education, Inc. 2 Platelets Positive feedback loop adhere to site and release chemicals. Slide 4 Figure 1.6 A positive feedback mechanism regulates formation of a platelet plug. 1 Break or tear occurs in blood vessel wall. Positive feedback cycle is initiated. 3 Released chemicals attract more platelets. 2 Platelets Positive feedback loop adhere to site and release chemicals. Feedback cycle ends when plug is formed. 4 Platelet plug is fully formed. © 2013 Pearson Education, Inc. Slide 5 Homeostatic Imbalance • Disturbance of homeostasis – Increases risk of disease – Contributes to changes associated with aging • Control systems less efficient – If negative feedback mechanisms overwhelmed • Destructive positive feedback mechanisms may take over (e.g., heart failure) © 2013 Pearson Education, Inc. Anatomical Position • Standard anatomical body position – Body erect – Feet slightly apart – Palms facing forward • Thumbs point away from body • Always use directional terms as if body is in anatomical position • Right and left refer to body being viewed, not those of observer © 2013 Pearson Education, Inc. Figure 1.7a Regional terms used to designate specific body areas. Cephalic Frontal Orbital Nasal Oral Mental Cervical Upper limb Acromial Brachial (arm) Antecubital Thoracic Sternal Axillary Mammary Antebrachial (forearm) Carpal (wrist) Abdominal Umbilical Manus (hand) Pollex Pelvic Inguinal (groin) Palmar Digital Lower limb Coxal (hip) Femoral (thigh) Patellar Pubic (genital) Crural (leg) Fibular or peroneal Pedal (foot) Tarsal (ankle) Thorax Abdomen Back (Dorsum) Metatarsal Digital Hallux Anterior/Ventral © 2013 Pearson Education, Inc. Table 1.1 Orientation and Directional Terms (1 of 3) © 2013 Pearson Education, Inc. Table 1.1 Orientation and Directional Terms (2 of 3) © 2013 Pearson Education, Inc. Table 1.1 Orientation and Directional Terms (3 of 3) © 2013 Pearson Education, Inc. Directional Terms Superior Cranial Proximal Posterior or dorsal (Away from midline) Lateral Medial (Toward or at midline) Caudal Proximal Distal Distal Inferior Anterior or ventral • Superficial – Toward or at the body surface Superficial • Deep – More internal – Away from body’s Deep surface Directional Term Practice • The forehead is __________ to the nose. • The forehead is superior to the nose. Directional Term Practice • The naval is ________ to the breastbone. Directional Term Practice • The naval is inferior to the breastbone. Directional Term Practice • The knee is _____________ to the thigh. Directional Term Practice • The knee is distal to the thigh. Directional Term Practice • The arms are ____________ to the chest. Directional Term Practice • The arms are lateral to the chest. Directional Term Practice • The breastbone is ________ to the spine. Directional Term Practice • The breastbone is anterior (ventral) to the spine. Directional Term Practice • The heart is ___________ to the arm. Directional Term Practice • The heart is medial to the arm. Directional Term Practice • The lungs are ________ to the rib cage. Directional Term Practice • The lungs are deep to the rib cage. Directional Term Practice • The elbow is __________ to the wrist. Directional Term Practice • The elbow is proximal to the wrist. Directional Term Practice • The skin is ________ to the skeleton. Directional Term Practice • The skin is superficial to the skeleton. Regional Terms • Two major divisions of body – Axial • Head, neck, and trunk – Appendicular • Limbs • Regional terms designate specific areas within body divisions © 2013 Pearson Education, Inc. Figure 1.7a Regional terms used to designate specific body areas. Cephalic Frontal Orbital Nasal Oral Mental Cervical Upper limb Acromial Brachial (arm) Antecubital Thoracic Sternal Axillary Mammary Antebrachial (forearm) Carpal (wrist) Abdominal Umbilical Manus (hand) Pollex Pelvic Inguinal (groin) Palmar Digital Lower limb Coxal (hip) Femoral (thigh) Patellar Pubic (genital) Crural (leg) Fibular or peroneal Pedal (foot) Tarsal (ankle) Thorax Abdomen Back (Dorsum) Metatarsal Digital Hallux Anterior/Ventral © 2013 Pearson Education, Inc. Figure 1.7b Regional terms used to designate specific body areas. Cephalic Otic Occipital (back of head) Upper limb Acromial Brachial (arm) Cervical Olecranal Antebrachial (forearm) Back (dorsal) Scapular Vertebral Lumbar Manus (hand) Sacral Metacarpal Gluteal Digital Perineal (between anus and external genitalia) Lower limb Femoral (thigh) Popliteal Sural (calf) Fibular or peroneal Pedal (foot) Calcaneal Back (Dorsum) Plantar Posterior/Dorsal © 2013 Pearson Education, Inc. Anatomical Variability • Humans differ externally and internally – 90% of all structures present in body match description in textbook – Nerve or blood vessel may be out of place – Small muscle may be missing • Extreme variations inconsistent with life © 2013 Pearson Education, Inc. Body Planes and Sections • Body plane – Flat surface along which body or structure may be cut for anatomical study • Sections – Cuts or sections made along a body plane © 2013 Pearson Education, Inc. Body Planes • Three most common – Lie at right angles to each other – Sagittal plane – Frontal (coronal) plane – Transverse (horizontal) plane © 2013 Pearson Education, Inc. Sagittal Plane • Sagittal plane – Divides body vertically into right and left parts – Produces a sagittal section if cut along this plane – Midsagittal (median) plane • Lies on midline – Parasagittal plane • Not on midline © 2013 Pearson Education, Inc. Body Planes • Frontal (coronal) plane – Divides body vertically into anterior and posterior parts – Produces a frontal or coronal section • Transverse (horizontal) plane – Divides body horizontally (90° to vertical plane) into superior and inferior parts – Produces a cross section • Oblique section – Result of cuts at angle other than 90° to vertical plane © 2013 Pearson Education, Inc. Figure 1.8 Planes of the body with corresponding magnetic resonance imaging (MRI) scans. Frontal plane Median (midsagittal) plane Transverse plane Frontal section (through torso) Transverse section (through torso, inferior view) Pancreas Median section (midsagittal) Aorta Spleen Arm Left and Liver Heart right lungs Stomach © 2013 Pearson Education, Inc. Liver Spinal cord Subcutaneous fat layer Body wall Rectum Intestines Vertebral column Body Cavities • Two sets of internal body cavities – Closed to environment • Provide different degrees of protection to organs • Dorsal body cavity • Ventral body cavity © 2013 Pearson Education, Inc. Dorsal Body Cavity • Protects nervous system • Two subdivisions: – Cranial cavity • Encases brain – Vertebral cavity • Encases spinal cord © 2013 Pearson Education, Inc. Figure 1.9 Dorsal and ventral body cavities and their subdivisions. Cranial cavity Cranial cavity (contains brain) Vertebral cavity Dorsal body cavity Thoracic cavity (contains heart and lungs) Vertebral cavity (contains spinal cord) Pleural cavity Pericardial cavity within the mediastinum Diaphragm Abdominal cavity (contains digestive viscera) Abdominopelvic cavity Pelvic cavity (contains urinary bladder, reproductive organs, and rectum) Dorsal body cavity Ventral body cavity Lateral view © 2013 Pearson Education, Inc. Superior mediastinum Anterior view Ventral body cavity (thoracic and abdominopelvic cavities) Ventral Body Cavity • Houses internal organs (viscera) • Two subdivisions (separated by diaphragm) – Thoracic cavity – Abdominopelvic cavity © 2013 Pearson Education, Inc. Ventral Body Cavity • Thoracic cavity subdivisions – Two pleural cavities • Each surrounds a lung – Mediastinum • Contains pericardial cavity • Surrounds thoracic organs – Pericardial cavity • Encloses heart © 2013 Pearson Education, Inc. Ventral Body Cavity • Abdominopelvic cavity subdivisions – Abdominal cavity • Contains stomach, intestines, spleen, and liver – Pelvic cavity • Contains urinary bladder, reproductive organs, and rectum © 2013 Pearson Education, Inc. Figure 1.9 Dorsal and ventral body cavities and their subdivisions. Cranial cavity Cranial cavity (contains brain) Vertebral cavity Dorsal body cavity Thoracic cavity (contains heart and lungs) Vertebral cavity (contains spinal cord) Pleural cavity Pericardial cavity within the mediastinum Diaphragm Abdominal cavity (contains digestive viscera) Abdominopelvic cavity Pelvic cavity (contains urinary bladder, reproductive organs, and rectum) Dorsal body cavity Ventral body cavity Lateral view © 2013 Pearson Education, Inc. Superior mediastinum Anterior view Ventral body cavity (thoracic and abdominopelvic cavities) Membranes in Ventral Body Cavity • Serous membrane or serosa – Thin, double-layered membranes • Parietal serosa lines internal body cavity walls • Visceral serosa covers internal organs (viscera) – Layers separated by slit-like cavity filled with serous fluid • Fluid secreted by both layers of membrane © 2013 Pearson Education, Inc. Serous Membranes • Named for specific cavity and organs with which associated • Each has parietal and visceral layers • Pericardium – Heart • Pleurae – Lungs • Peritoneum – Abdominopelvic cavity © 2013 Pearson Education, Inc. Figure 1.10 Serous membrane relationships. Outer balloon wall (comparable to parietal serosa) Air (comparable to serous cavity) Inner balloon wall (comparable to visceral serosa) A fist thrust into a flaccid balloon demonstrates the relationship between the parietal and visceral serous membrane layers. Heart Parietal pericardium Pericardial space with serous fluid Visceral pericardium The serosae associated with the heart. © 2013 Pearson Education, Inc. Abdominopelvic Quadrants • Divisions used primarily by medical personnel © 2013 Pearson Education, Inc. Figure 1.11 The four abdominopelvic quadrants. Right upper quadrant (RUQ) Left upper quadrant (LUQ) Right lower quadrant (RLQ) Left lower quadrant (LLQ) © 2013 Pearson Education, Inc. Abdominopelvic Regions • Nine divisions used primarily by anatomists © 2013 Pearson Education, Inc. Figure 1.12 The nine abdominopelvic regions. Right hypochondriac region Right lumbar region Right iliac (inguinal) region Epigastric region Umbilical region Hypogastric (pubic) region Left hypochondriac region Left lumbar region Left iliac (inguinal) region Nine regions delineated by four planes © 2013 Pearson Education, Inc. Diaphragm Liver Spleen Gallbladder Stomach Ascending colon of large intestine Transverse colon of large intestine Small intestine Descending colon of large intestine Cecum Appendix Initial part of sigmoid colon Urinary bladder Anterior view of the nine regions showing the superficial organs Other Body Cavities • Exposed to environment – Oral and digestive cavities – Nasal cavity – Orbital cavities – Middle ear cavities • Not exposed to environment – Synovial cavities © 2013 Pearson Education, Inc.
