Final exam for anatomy
Anatomy
Science of body structures and their relationships
physiology
Science of body funcitons
Scientific Method
Observation
Use of senses to notice and study a Phenomenon
Scientific Method
Hyposthesis
Poential testable explanation for a phenomenon, based on observatrions and prior knowledge and experience
Scientific Method
Experiment
Implementation of specific materials and methods designed to test a hypothesis
(should include a control group and experimental group)
Scientific Method
Data
Results generated by conducting experimental tests
Scientific Method
Conclusion
Statements based on analysis of test results that discusss evidence to support or reject the hypothesis
Scientific Theory
Widely accepted concepts based on extensive experimental evidence
Scientific laws
Also based on the extensive experimental evidence, but arise from numerous studies that have been shown to produce exactly the same results every time under the same circumstances
Homeostasis
Condition of equilibrium in the body's internal environment due to the constant interplay of all the body's regulatory processes
Metabolism
Sum of all chemical processes that occur in the human body
Catabolism
Phase of metabolism that invovles breaking down complex chemical substances into simpler ones;= decompostion reactions
Anabolism
Phase of metabolism that involves building complex chemical substances from smaller, simpler ones; = synthesis reactions
Disorder
Any abnormality of function
Disease
Illness characterized by a recognizable set of signs and symptoms
Symptoms
Subjective changes in body functions not apparent to ovbserver
Ex. Headache, Nausea
Signs
Objective Changes a clinician can observe and measure
Ex. Swelling, rash, fever, high blood pressure
Element
Substance that cannot be split into a simpler substance by ordinary chemical means
Atoms
Smallest units of matter that retain the properites and characteristics of an element
Atomic Number
Number of protons in nucleus of an atom of an element since number of elcetrons equals the number of protons, atomic number reveals number of electrons
Mass number
Sum of protons and neutrons in an atom
Atomic mass (weight)
Average of all naturally occurring stable isotopes of a given element in AMU (daltons)
Isotope
Atoms of element that have different numbers of neutrons and thus different mass numbers, but have same number of protons and electrons, so same chemical properties
Ion
Atom that has a positive or negative charge due to giving up or gaining electrons(ionization). which results in unequal number of protons and electrons
Molecule
Two or more atons (same or different) joined together by sharing of electrons
Compound
Substance that contains two or more different elements
Ionic bond
Force of attratcion tha holds ions having opposite charges together
Nonpolar covalent bond
Two or more atoms (same or different) share one or more pairs of their valence electrons equally
Polar Covalent bond
Two or more atoms (same or different) share one or more pairs of their valence electrons unequally equally and results in partial negative charge near atom with greater electronegativity and partial postive charge near other atoms
Hydrogen (H) bonds
Occur between polar molecules that contain polar covalent bonds betweeen H and very electonegative atons, such as O-H, N-H, or F-H bonds
Exergonic reaction
Release more energy than it absorbs
Endergonic Reaction
Absorbs more energy than it releases
Oxidation-Reduction redox reactions
Special type of exchange reaction that involves trnsger of electrons between atoms or molecules
Use of periodic table
Determine atomic number, mass number, atomic mass, number of protons, electrons, and neutrons, filling of electron shells, ionization
Inorganic Compounds
In general, lack carbon and are stucturally simple include water, many salts, acids, and bases
organic compounds
Contain carbon and many are relatively large and have unique characteristics that allow them to carry out complex functions include carbohydrates, lipids, proteins, nucleic acids and ATP
Adenosine triphosphate (ATP)
Major source of energy used to power reactions in body that require energy
-Most ATP in the cell is produced in mitochondtria
-Most ATP in th cell is produced by aerobic cellular respiration
6 Major Nutrients
WATER,VITAMINS, MINERALS, CARBOHYDRATES, LIPIDS, PROTEINS
Water - most important and abundant inorganic compound in all living systems
Glycogen - Storage form of carghydrates
Triglycerides - Storage form of lipids
Proteins - are not sroted for future use
Level 1 of protein structural organization
Primary
Unique aa sequence joined by covalent peptide bonds
Level 2 of protein sturctural organization
Secondary
Repeated twisting or folding of neighboring amino acids in polypeptide chain
(alpha helixes and pleated sheets)
Level 3 of protein structural organization
Tertiary
3-D folding pattern formed by various bonds; determines shape and how a protein will function
Level 4 of protein structural organization
Quaternary
Arrangement fo two or more polypeptide chains relative to each other
Acid
Below pH 7 , proton (H+) donor, dissociates into H+ and anions
Base
Above pH7, proton (H+) acceptor, dissociates into cations and OH- or another proton acceptor, such as NH3
Salt
Dissociates into cations and anions, neither of which is H+ or OH-
Acid + base -> Salt + Water
Buffer
Substance that resists drastic changes in pH (maintains pH0 by convering strong acids or bases into weak ones
Plasma membrane
Encloses and protects cell and contains functional proteins such as enzymes that catalyze chemical ractions, receptors that bind ligands and regulate cellular activity, transporters that regulate qwhat enters and exits cell, and cell identity markers
Cytoplasm
Cellular contents between the plasma membrane and the nucleus includes cytosol and organelles
Cytosol
Fluid that surrounds organelles
Organelles
Specialized structures with characteristic shapes and specific functions in cell growth, maintenance, and reproduction: include nucleus, nucleoli, ribosomes, rough ER, smooth ER, Golgi apparatus, mitochondria, centrioles, lysosomes, peroxisomes, and other structures
Nucleus
Spherical or oval-shaped sturcute where most of cell's DNA and nucleoli are located
"control cneter fo the cell"
Nucleoli
One or more spherical bodies in nucleus that are sites of rRNA synthesis and assembly of rRNA and proteins into ribosomal subunits
Ribosomes
Site of protein synthesis attached to nuclear envelope and rough ER, free in cytosol, and in mitochondria
Rough endoplasmic reticulum (RER)
Network of folded membranes with attached ribosomes that synthesize proteins, which then enter RER for processing and sorting synthesizes glycoproteins and phospolipids
Smooth endoplasmic reticulum (RER)
Network of folded membranes (with no ribosomes) that synthesizes fatty acids and steroids and may have other functions, such as detoxification of harmful substances, depending on cell type
Golgi apparatus
Modifies and packages proteins syntheseized in rough ER for tansport
Mitochondria
Genreate most of cell's ATP for enery to drive cellular activities
"powerhouse of the cell"
Centrioles
form mitotic spindle during cell division and involved in construction of structures such as flagella and cilia
Lysosomes
membrane-enclosed vesicles that contain digestive and hydrolytic encymes that breakdown foreign cells, worn out organelles, and a wide cariety of molecueles
Peroxisomes
Contain oxidative enzymes that can deactibate hrmful substances
Structural framework of cell's plasma membrane is a lipid bilayer
Two back to back layers made up of prmarily phospholipids plus cholesterol and glycolipids
"Fluid mosaic model"
Moving sea of fluid lipids with a mosaic of different functional proteins
Selectively permeable
Allows free passage of many lipid-soluble molecules but selectibely controls crossing of ions or polar substances through transporter proteins
Mitosis
Consists of nuclear division during cell division that produces two identical daughter cells with diploid number of chromosomes; mainly in somatic cell division
4 phases
Prophase
anaphase
metaphase
telophase
Cytokinesis
Cytoplasmic division during cell division begins in late anaphase, completed in telophase
Interphase
Perios between cell divisions during which cell is functionally and metabolically active and also undergoes growth and duplicates its DNA, organelles, and cytosolic components in anticipation of cell division
Meiosis
Reproductive cell divbison that produces gametes (oocytes in females and sperm in males0 in which the number of chromosomes in the nucleus are reduced by half (haploid Number)
DNA Replicaton
Synthesis of DNA from DNA template
Transcription
Synthesis of mRNA from DNA template
Translation
Synthsis of amino acid sequence of protein from mRNA template
Structure of DNA
-Double strande and has double helix structure resembling spiral ladder
-sides of ladder are formed by alternation deoxyribose sugars and phosphate groups
-rungs are formed by nitrogenous base pairs joined to each other by hydrogen bonds
-4 nirogenous bases: Guanine (G), Cytosine (C), Adenine (A), and Thymine (T)
Thymine pairs with adenine
Guanine paris with Cytosine
Structure of RNA
-differs from DnA
-Single-stranded instead of double-stranded
-Contains ribos instead of deoxyribose
-contains uracil rather than thymine
Uracil pairs with adenine
Guanine pairs with Cytosine (same in DNA)
3 kinds of RNA made from DNA template
Messenger RNA (mRNA)
Ribosomal RNA (rRNA)
Trnsger RNA (tRNA)
Messenger (mRNA)
Directs proten synthesis
Ribosomal RNA (rRNA)
Joins with ribosomal Proteins to make ribosomes
Transfer (tRNA)
One end binds specific amino acid and other end has anticodon that base pairs with complimentary codon on mRNA, to hold amino acid in place on ribosome until it is incorporated into protein during translation
Codon (in mRNA)
each sequence of 3 nucleotides in mRNA that base-pairs with a DNA base triplet
Anticodon
Nucleotide triplet on tRNA that base pairs with complimentary mRNA codon
Introns
Regions within gene that do not code for parts of protein
Exons
Regions within gene that do code for parts of protein
Passive transport
substance uses its own kinetic energy to move down it concentration or electrochemical gradient across membrane until it reaches equilibrium (equal on both sides); does not require energy
Simple diffusion through lipid bilayer
allows passage of nonpolar substances
Facilitated diffusion through channels
allows passage of larger and highly polar/charged substances via transporter protein
Active transport
Energy-requiring process in which transport proteins move solutes across membrane against (up) concetration gradient
Primary active transport
enery derived from hydrolysis of ATP to "Pump" substance across membrane against (Up) its concentration gradient
Secondary Active transport
Harnesses potential energy of steep NA+ or H+ concentration gradient (established by primary atibe transport of these ions) to transport substance up its concentration gradient as Na+ or H+ move down their concetration gradient
Symporters
Move two or more substances in same direction
Antiporters
Move two or more substances in oppostie directions
Vesicle transport
Vsicles, small sacs that bud off from an existing membrane, transport substances between structures within cell or in and out of cell
Endocytosis
materials move into a cell in a vesicle formed by plasma membrane
Exocytosis
Membrane enclose "secretory" vesicles form inside cell, fuse with plasma membrane, and release their contents into extracellular fluid
Osmosis
Net movement of water across membrane not permeable to solutes
Tonicity
Measure of solution's ability to change volume of cells by altering their water content
Isotonic solution
concentrations of solutes same on both sides of membrane, so water enters and exits at same rate and cells maintain normal shape and volume
Hypotonic solution
has lower concentration of solutes than cytosol, so water enters cells faster than it leaves casuing cells to swell and burst
Hypertonic solution
has higher concentration of solutes than cytosol, so water moves out of cells faster than it moves in causing cells to shrink
Cell junctions
Contact points between plasma membrane of tissue cells
tight junction
Transmembrane proteins fuse adjacent cells' plasma membranes togher to retard the passage of substances and rom water tight seal so common in urinary and digestive tracts
adherens junction
Cells are joined by cadherin proteins of adjacent cells that insert into protein plaques inside plasma membrane so help epithelial surgaces resist separation
Desmosomes
have plaques and cadherins that attach cells to one another, but also have intermediate filaments that extend from desmosomes on one side fo cell across cytosol to desmosomes on opposite side of cell to prevent cells from separation under tension so common in epidermis and cardiac muscle
Hemidesmosomes
similar to desmosomes but contain integrins, rather than cadherins and anchor cells to basement membrane between epithelium and connective tissue
Gap Junction
membrane proteins called connexins form tiny fluid-filled tunnels called connexons that connect neighboring cells and allow rapid communictaion and diffusion of substances between the cells so common in nervous tissue and cardiac muscle
body tissue
epithelial tissue
covers body surface
body tissue
Connective tissue
protcets and supports body and organs
body tissue
muscle tissue
generates physical force neeeded to make body structures move
body tissue
Nervous tissue
detects changes in conditions inside and outside of body and responds by generating nerve impulses that control other tissues help maintain homeostasis
exocrine Gland
Sudoriferous glands
exocrine glands that secrete sweat into hair follicles or onto the skin's surface to lower body temperature
exocrine gland
sebacous glands
Exocrine glands connected to hair follicles that secrete an oily substance to help prevent hair and skin from drying out
exocrine gland
Ceruminous glands
modified sweat glands in external auditory canal that secrete ear wax to impede entrance of foreign particles
exocrine glands
Goblet cells
Unicellular exocrine glands that secrete mucus to help lubricate and protect lining of GI tract and help trap foreign particles in respiratory tract so they can be moved back out by cilia
Connective tissue (CT)
includes tissues such as adipose (loose CT), tendons and ligaments (dense CT), cartilage, bone, blood and lymph
-binds togeether, supports, and strengthens other tissues (loose and dense CT)
-Protects and insulates internal organs (adipose)
-Compartmentalizes structures such as skeletal muscles (loos and dense)
-Major transport system(blood)
-Stored energy reserves (adipose fat tissue)
-Main site of immune responses (lymph and white blood cells
Muscle tissue
Muscle fibers use ATP to generate force
-3 types: Skeletal, cardiac, and smooth
Muscle tissue
Skeletal
usually attached to bones of skeleton, boluntary and striated (alternating light/dark bands on stained fibers)
Muscle tissue
Cardiac
Forms most of wall of hear, involuntary, branched, striated and contains intercalated discs (with gap junctions and desmosomes)
Muscle tissue
Smooth
Located in walls of hollow organs (blood vessels, airways, digestive, urinary, reproductive), involuntary, and nonstriated
Nervous tissue
Controls and integrates all body activities within limits that maintain life
Basic functions of nervous tissue
sensing nternal and external changes with sensory receptors processing, interpreting, and remembering those changes with effectors (muscles and glands)
Neuron
functional unit of nervous system; has the capactiy to produce action potentials receive and conduct nerve impulses
neuroglia
nervous system cells that have supportive roles do not receive or conduct nerve impulses
integumentary system
Includes skin, hair, and nails
Skin
Covers body, protects underlying tissues, and contains accessory structures that function in protection from microbes and sun, thermoregulation, and tactile sensations
eccrine suderiferous (sweet) glands
exocrine glands found throughout most of body that secrete sweat into hair follicles or onto the skin's surgace to lower body temperature
sebaceous (oil) glands
exocrine glands connected to hair follicles that secrete an oily substance to help prevent hair and skin from drying out
arrector pili muscle
smooth muscle near hair that is stimulated by autonomic nervous system to contract under sonditions of stress (such as cold or fright)
Meissner's corpuscle
encapsulated nerve ending that senses light touch
Pacinian corpuscle
encapsulated nerve ending that detects deep pressure
functions of skeletal system
support
structural framework for body; supports soft tissues and provides attachment points for tendons of most skeletal muscles
functions of skeletal system
Protection
protects many internal organs from injury
functions of skeletal system
movement
bones and muscles work together to produce movement: muscles are attached to bones, so when they contract, they pull bones
function of bone tissue
Mineral homeostasis
Several minerals, mainly calcium and phosphorus, are stored in bone tissue and realeased on demand into blood to maintain critcial mineral balcnces and to distribute minerals to other parts of body
function of bone tissue
blood cell production (hemopoieis or hematopoiesis)
function of red bone marrow (in spongy bone) occurs in skull, ribs, sternum, vertebrae, pelvis, and ends of arm and thigh bones produces red blood cells, white blood cells, and platelets
function of bone tissue
Triglyceride storage
function of yellow bone marrow consists mainly of adipocytes, which store triglycerides serves as important eneregy resrve (triglycerides)
Flexion
decrease in angle
extension
increase in angle, usually restorying to anatomical position
abduction
movement of a bone away from the midline
adduction
movement of a bone toward the midline
circumduction
mocement at distal end of body part in a circle (continuous sequence of flexion, abduction, extension and adduction)
ratation
bone revolves around its own longitudinal axis
supination
movement of forearm to turn palm anteriorly or superiorly
pronation
movement of forearm to turn palm posteriorly or inferiorly
sarcomeres
basic functional units of a myofibril in muscle, separated by Z discs
myofibrils
composed of 3 types of proteins (name proteins included in these 3 groups and describe their functional roles in sliding filament model of muscle contraction)
contractile Proteins
Actin and myosin
actin
in thin filaments
myosin
in thick filaments
regulatory proteins
troponin and tropomysosin in thin filaments
structural proteins
titin, M line, dystropin, nebulin muscle action potential is stimulated by acetylcholine (neurotransmitter) realeased from motor neuron at neuromuscular junction that binds receptors on muscle cell membrane and leads to depolarization of membrane to threshold potential via opening of Na+ channels: be familiar with steps in generation muscle action potentials and muscle contractions
resting membrane potential
-90 mV
threshold Potential
-55 mV
Depolarizarion (potential becomes more positivve, moves toward threshold potential
involves opening of Na+ ion channels and produces action potential if threshold is reache, which causes opening of more Na+ channels and leads to contraction due to opening fo voltage-gated Ca++ channels
Sliding filament mechanism of skeletal muscle contraction
heads of myosin bind and form crossbrides with actin and pull the thin filaments toward the M line (midline); requires energy from ATP hydrolysis
-in relaxed muscle (no Ca2+ present), tropomyosin, held in place by troponin, covers myosin binding sites on actin and prevents the formation of crossbridges
-when sufficient Ca 2+ is present, it binds to troponin, which changes shape and moves tropomyosin, therby expsoing binding sites to allow crossbridge formations
Resting membrane prential in a neuron
-70 mV
Resting membrane potential in a muscle cell
-90 mV
Grades potentials
small local changes from resting membrane potential
depolarization
membrane becomes more positive can build to threshold potential, so excitatory
Hyperpolarization
membrane becomes more negative makes it less likely to reaach threshold, so inhibitory
threshold potential
-55 mV
Depolarizing potential required to generate an action petential
Central nervous system (CNS)
Consists of brain and spinal cord
Peripheral nervous system (PNS)
consists of the cranial nerves and spinal nerves, which contain both sensory and motor fibers
Divisions of nervous system (PNS)
Somatic (voluntary) nervous system (SNS)
Sensory neurons from skin and special sensory receptors to the CNS motor neurons to skeletal muscle
Autonomic (involuntary) nervous systems (ANS)
sensory neurons from viscral organs to CNS motor neurons to cardiac muscle, smooth muscle, and glands
sympathetic division
"fight or flight" stress and emergency responses
Parasympathetic division
"rest and digest" maintenance of homeostasis usually dominates
enteric nervous system (ENS)
Involuntary sensory and motor neurons that control gastrointestinal tract
neuron
Functional unit of nervous system
-conducts (sends and receives) nerve impulses to communicate with and control actions of other cells
Dendrites
one to many short, branched processes that receive input and conduct graded porentials toward cell body
axons
one thin, typically long process that conducts nerve impulses away from cell body (sends output) and releases neurotransmitter from synaptic end bulbs at ends of axon terminals
only one present, but branches to make many contacts most are myelinated
neuroglia
nervous system cells that have supportive roles
-do not conduct nerve impulses
neuroglia in the CNS
Astrocytes
maintain chemical environment in CNS and help form the blood-brain barrier
Neuroglia in the CNS
microglia
phagocytic role
Neuroglia in the CNS
Oligodendrocytes
form myelin sheath around CNS axons
Neuroglia in the CNS
Ependymal cells
line the cerebral cavities and produce cerebrospinal (CSF) fluid
Neuroglia in PNS
Schwann cells
Form a myelin sheath around PNS axons
Neuroglia in PNS
Satellite cells
role not clear, but believed to maintain chemical environment in PNS
Axons of PNS neurons
most covered by myelin sheaths produced by schwann cells
nodes of ranvier
gaps between myelin sheaths where many voltage-gated channels are located
myelinated fibers
myelin acts as electrical insulator and speeds conduction of nerve impulses
unmyelinated fibers
slow because small diameter and no myelin insulation
saltatory conduction
rapid nerve conduction that occurs in myelinated fibers where signal jumps node to node of Ranvier
continuous conduction
slow nerve conduction that occurs in unmyelinated fibers where entire length of axon must be depolarized step by step
Neurotransmitters
Released from axon terminals,diffuse across synaptic cleft, and bind to receptors on target cell; may be excitatory or inhibittory
Acetylcholine (ACh)
Excitatory on neuromuscular junction but inhibitory at others
glutamate
Major excitatory on neurotransmitter in CNS and PNS
Aminobutyric acid (GABA)
major inhibitory neurotransmmitter in forebrain
norepinephrine
regurlates mood, dreaming, awakening from sleep
dopamine
regulates skeletal muscle tone
serotonin
regurlates mood, temperature, and induction of sleep
Neuropeptide
Substance P
enhances perception of pain
Neuropeptide
Enkephalins (opioids)
relieve pain by blocking the release of substance P
spinal cord nerve tracts
pathways for travel of sendory and motor information
ascending nerve tracts
carry sensory information from spinal cord to brain
descending nerve tracts
carry motor information from brain to spinal cord
diencephalon
extends from brain stem to cerebrum and surrounds third ventricle
thalamus
Relays almost all sensory input to the cerebral cortex
hypthalamus
controls and integrates activities of the autonomic nervous system and the pituitary gland
epithalamus
contains pineal gland, which secretes melatonin to promote sleepiness
-Subthalamus containing subthalamic nuclei that work with the basal ganglia to help control body movements
brain stem
portion of brain between spinal cord and diencephalon
Medulla Oblongata
-lower part of the brain stem
-relays motor and sensory impulses between other parts of the brain and spinal cord
-has a crdiovascular center that regulates the force and rate of heartbeat and diameter of blood vessels
-has a respiratory center that adjusts the rhythm of breathing
Pons
-middle part of the brain stem
-relays impulses from one side of the cerebelllum to other and between medula and midbrain
-has pnneumotaxic and apneustic area to help control breathing
Midbrain
-upper part of the brain stem
-relays motor impulses from cerebral cortex to pons and sensory impulses from spinal cord to thalumus
-includes the red nuclei, which function with the cerebellum to coordinate muscular movements
-includes substantia nigra that releases dopamine for regulating muscle tome
cerebellum
posterior to medull and pons and inferior to posterior cerebrum
Functions: Coordinate complex, skilled movements
Reulate posture and balance
May have role in cognition and language processing
cerebrum
Consists of cerbral corex (ouoter rim of gray matter), white matter (interior), and gray matter nuclei deep within white matter
-divided into right and left hemispheres
-each hemispher receives sensory input from and controls muscles on opposite side of body
hemispheric lateralization
functional symmetry between the two hemispheres
left hemisphere
in most people, more important for reasoning, numeric, and scientific skills, language
Right Hemisphere
more specialized for art and music, spacial and pattern perception, emotional content of language, and face recognition
5 lobes
Frontal
Parietal
Occipital
Temporal
Insula
Cerebral Cortex
Primary sensory areas
Receive nerve impulses for specific stimuli determines location and basic characteristics of stimuli
Cerebral Cortex
Primary motor area
controls voluntary contractions of specific muscles or muscle groups
Broca's speech area
brain region where planning and production of speech occurs
aphasia
inablitlity to use or comprhend words caused by injury to language areas
Sensory association (secondary sensory) areas
usuallly receive input from primary sensory areas and other brain regions, including thalamus integrate/interpret sensory info by comparing with past sensory (memory)
premotor area
motor association area that controls learned skiloled movements and stores memory for such movements
basal ganglia
3 nuclei deep within each cerebral hemisphere that help regulate intiation and termination of movements
limbic system
has primary role in emotions, olfaction, and memory
reticular activating system (RAS)
involved in stimulatin and maintaining arousal and consciousness
Learning
acquiring new knowledge
memory
process of retaining and retrieving information
brain waves
collection of action potentials and graded potentials generated by neurons in brain
Electoencephalogram (EEG)
record of brain wabes (electrical signals) used for studying normal brain activity and diagnosing disorders such as tumor, trauma, and epilepsy
sleep
state of latered or partial consciousness from which a person can be aroused
2 components
non-rapid eye movement (NREM) and rapid eye movement (REM) sleep
-REM and NREM alternate throughout sleep
-Most dreams occur during REM sleep
-sleep deprivation impairs attention, learning and performance
Proprioceptors
sense joint postiiont and movement and muscle length and tension
nocioceptors
sense pain found in all tissues of the body except the brain
Thermoreceptors
sense warmth or cold
tactile receptors
sense tough, pressure, vibration, tickle, and itch
Special senses
olifaction, gestation, vision, hearing and equilibrium involve much more complex, specialized receptors that somatic sensations
gustation
sense of taste
-chemical sense in shich tastants are dissolves in saliva and detected by gustatory hairs in taste buds
taste buds
detect 5 gustatory stimuli (bitter, sour, sweet, salty, and umami-meaty/savory)
-taste on the anterior 2/3 of the tongue comes from sensory axons of the facial nerve
-taste on the posterior 1/3 of the tongue arises from sensory axons of the glosssopharyngeal nerve
Olfaction
Sense of smell
-Chemical sense in shich odorants are dissolved and detected by olfactory hairs of olfactory receptors
olfactory nerve (cranial nerve 1)
formed by bundles of olfactory receptor (1st order neurons)axons that terminate in olfactory bulb
olfactory tract
formed by axons of olfactory bulb neurons (2nd order neurons) that project to lateral olfactory are in temporal lobe
Cornea
transparent and vurved coat that covers iris that functions in refraction of litht:helps focus light onto retina
lens
refracts light: helps focus light on macula lutea of retina to provide clear images
Iris
Colored portion of eye that faces anteriorly
Pupil
hole in center that functions to regulate amount of light entering eye changing size of pupil is regulated by autonomic reflexis
parasympathetic reflex
circular muscles contract in bright light to constrict pupil
sympathetic reflex
radial muscles contract in dim light to dilate pupil
retina
serves as beginning of bisula pathway
optic disc
site where optic nerve exits back of eyeball
blined spot because contains no photoreceptors (rods and cones)
Retinas 2 layers
pigmented and neural
pigmented epithelium
nonvisual portion that has melanin
absorbs stray light and help keep image sharp and clear
nueral layer
multilayered outgrowth of brain that processes visual input then sends nerve impulses down axons that form optic nerves
Photoreceptors in retina
named for shape of their outer segment
rods
photoreceptors active in dim light that detect shades of gray contains photopigment called rhodopsin
Cones
photoreceptors active in bright light with photopigments to detect color each one caontains one of 3 different photopigments (opsins) for color produce sharper vision than rods
emmetropic eye
Normal eye that can sufficiently refract light rays from an object 20ft away so that a clear image is focused on the retina
Myopia
nearsightedness
occurs because eyeball is too long relative to focusing power of cornea and lens
hypermetropia (hyperopia)
Farsightedness
Occurs because eyball is too short relative to focusing power of cornea and lens
astigmatism
parts of image are out of focus, producing blurred or distorted vision occurs due to irregular curvature of cornea
Three major processes involved in image formation
-refraction (bending) of light by cornea and lens to focus light rays onto retina
-accommodation of lens: incresing curvature of lens so light is still focused as objects move closer to eye
-constriction of pupil to prevent light rays from entering through periphery of lens which minimizes blurriness
auricle
collects sound waves
external auditory canal (meatus)
directs sound waves to tympanic membrane
tympanic membrane (eardrum)
vibrated by sound waves, which vibrates ear ossicles in turn
auditory (ear) ossicles
transmit and amplify vibrations to oval window include: malleus, incus, and stapes
cochlea
contains series of fluids, channels, and membranes that transmit vibrations to organ of Corti for hearing
organ of corti
contains hair receptor cells that produce receptor potentials, which elicit nerve impulses in cochlear branch of vestibulocochlear nerve (cranial nerve VIII)
ventually nerve impulses reach primary and secondary auditory areas involved in awareness and interpretation of sound
vestibular apparatus
contains receptor organs for snse of equailibrium
includes: semicircular ducts, utricle, and saccule
Movement of sterocilia on hair cells of saccule and utricle leads to generation of nerve impulses in vestibular branch of vestibulocochlear nerve (cranial nerve VIII)
Static equilibrium
maintance of body position (mainly the head) relative to the force of gravity
Dynamic equilibrium
maintance of body position (mainly the head) during sudden mmovements such as rotation, acceleration, or deceleration
semicircular ducts
contains hair (receptor) Cells for dynamic equilibrium
Utricle and saccule
contain hair cells for dynamic and static equilibrium