A&P Final Exam

Question 1

Adrenal Medulla

Answer 1

innervated by sympathetic neurons (Chromaffin cells)
Releases norepinephrine or epinephrine (small amounts of dop)
Causes increased:
BP, heart rate, blood flow to skelatal muscle, pulmonary air flow
Inhibits digestion and urination

Question 2

Chromaffin cells

Answer 2

modified neurons - secretory cells that release into blood stream

Question 3

adrenal cortex

Answer 3

Produces 25 steroid hormones (corticosteroids)

Question 4

Categories of Corticosteroids

Answer 4

1. mineralocorticoids: regulates electrolytes
2. glucocorticoids - regulate metabolism of glucose
3. sex steroid - repro. functions (androgens)

Question 5

Zona glomerulosa (adrenal cortex)

Answer 5

secretes aldosterone in resp to blood Na content and angiotensin 2 from lungs
Increases reabsorption of Na+ and water in kidneys, maintains blood volume

Question 6

Aldosterone

Answer 6

principle mineralocorticoid produced in zona glomerulosa

Question 7

Zona Fasciculata and reticularis glucocorticoids

Answer 7

primarily secretes cortisol in resp to ACTH from anterior pituitary
Regulates metabolism by stimulating fat and protein catabolism, as well as as release of fatty acids and glucose into blood (makes nutrients available for ATP production)
Anti-inflammatory effects (steroid creams)
inhibits white blood cells and reduces release of histamine from mast cells, decreases capillary permeability

Question 8

Androgens from Zona Fasciculata and reticularis

Answer 8

small amounts of androgens produced
Major androgen: dehydroepiandrosterone –> testosterone (large quantities produced in testes, so this is unimportant for males in this location; important for females (sex drive))
Estradiol (adrenal estrogen)

Question 9

Estradiol

Answer 9

while ovaries produce much more than that derived from zona fasciculata and reticularis, helps to sustain bone mass after menopause

Question 10

Pancreatic Hormone

Answer 10

1-2 million pancreatic islets producing hormones
clusters of endocrineccells
other 98% of organ produces digestive enzymes (exocrine)

Question 11

Pancreatic Hormone

Answer 11

1-2 million pancreatic islets producing hormones
clusters of endocrine cells
other 98% of organ produces digestive enzymes (exocrine)

Question 12

Pancreatic Islets

Answer 12

types of cells: alpha, beta, delta, PP (F), G

Question 13

alpha cells

Answer 13

glucagon raises blood glucose levels by increasing rates of:
glycogen breakdown in skeletal muscle
glucose release by liver
fat breakdown in adipose

Question 14

beta cells

Answer 14

insulin secreted after meal with carbohydrates raises glucose blood levels
stimulates glucose and amino acid uptake
nutrient storage effect (stimulates glycogen, fat, and protein synthesis)
stimulation of fatty acid absorption in adipocytes)

Question 15

Delta Cells

Answer 15

produces somatostatin
inhibits GH (it’s GHIH)
secreted concurrently with insulin
may modulate secretion of alpha and beta cells

Question 16

G cells

Answer 16

secrete gastrin which stimulates stomach secretions, motility, and emptying

Question 17

PP (F) cells

Answer 17

produce pancreatic polypeptide (PP)

inhibits gallbladder contractions and regulates production of some pancreatic enzymes

Question 18

Thrifty genotype

Answer 18

high rates of obesity
rapid production of insulin when food is ingested
permits body to lay down efficiently
may be adapted to environments characterized by feast and famine

Question 19

Regulation of glucagon and insulin secretion

Answer 19

Low blood glucose stimulates release of glucagon

High blood glucose stimulates secretion of insulin

Question 20

Corpus luteum

Answer 20

follicle after ovulation

produces estradiol and progesterone for 12 days or 8-12 weeks with pregnancy

Question 21

Functions of estradiol and progesterone

Answer 21

development of female reproductive system and physique including bone growth
regulates menstrual cycle, sustains pregnancy
Preps mammary glands for lactation

Question 22

interstitial cells of testes

Answer 22

exists between seminiferous tubules

produces testosterone and estrogen

Question 23

functions of testes

Answer 23

development of male reproductive system and physique

Sustains sperm production and sex drive

Question 24

Sustentacular sertoli cells (nurse cells)

Answer 24

secretes inhibin which suppresses FSH secretion and stabilizes sperm production rates

Question 25

Heart

Answer 25

atrial natriuretic peptide (AMP) released in response to low BP by raising it

Question 26

Skin

Answer 26

keratinocytes helps produce D3, first step in synthesis of calcitriol

Question 27

Liver

Answer 27

converts vitamin D3 to calcidiol
source of IGF (insulin-like growth factor) that works with GH
secretes about 15% of erythropoietin
Secretes angiotensinogen
precursor of angiotensin 2 (vasoconstrictor) raises BP

Question 28

Kidneys

Answer 28

converts calcidiol to calcitriol (active form of vit D)
incr. absorption by intestine and inhibits loss in urine
more Ca2+ available for bone deposition
produces 85% of erythropoietin
converts angiotensinogen to angiotesin 1 with renin

Question 29

erythropoietin

Answer 29

stimulates bone marrow to produce RBC’s

Question 30

Lungs

Answer 30

converts angiotensin 1 to angiotensin 2 (vasoconstrictor)

Question 31

stomach and small intestines (10 enteric hormones)

Answer 31

coordinate digestive motility and secretion

Question 32

Placenta

Answer 32

secretes estrogen, progesterone, and others

regulates pregnancy, stimulates development of fetus and mammary glands

Question 33

down regulation of hormone receptors

Answer 33

receptors are degraded, decrease sensitivity of target cell to hormone

Question 34

Up regulation of hormone receptors

Answer 34

targets tissue more sensitive to the hormone and increase receptor production

Question 35

Gen mechanism of hormone action

Answer 35

hormone binds to cellular surface or receptor inside target cell
cell may then synthesize new molecules, change permeability of membrane, or alter rates of reaction

Question 36

Permissive effect

Answer 36

second hormone that strengthens effects of first

ex: estrogen stimulates up regulation of progesterone receptors in uterus

Question 37

synergistic effect

Answer 37

two hormones acting together for greater effect
Ex: estrogen and LH both needed for oocyte development
FSH and testosterone both needed for sperm production

Question 38

Antagonistic effect

Answer 38

two hormones with opposite effects

insulin promotes glycogen formation and glucagon stimulates glycogen breakdown

Question 39

stress response

Answer 39

set of bodily changes called general adaptation syndrome (GAS)

Question 40

Primary sex organs

Answer 40

organs that produce the gametes (testes or ovaries)

Question 41

Secondary sex organs (accessory but essential for reproduction)

Answer 41

male = ducts, glands, and penis 
females = uterine tubes, uterus, vagina that receive sperm and nourish the developing fetus

Question 42

Secondary sex characteristic

Answer 42

features that develop at puberty to attract a mate

pubic, axillary and facial hair, scent glands, body morphology

Question 43

Somatic cells (diploid)

Answer 43

23 pairs of chromosomes for total of 46
each pair is homologous - contains similar genes
one member of each pair is from each parent
22 autosomes and 1 pair of sex chromosomes (either X or Y)

Question 44

Gametes (haploid cells)

Answer 44

single set of chromosomes for total of 23

produced by special type of division: meiosis

Question 45

Testes

Answer 45

paired oval glands measuring 2 in by two inc
surrounded by dense CT white capsule (tunic albuginea)
Fibrous partitions (septa) form 200-300 lobules
Each is filled with 2 or 3 seminiferous tubles where sperm are formed

Question 46

Tunica Vaginalis

Answer 46

serous membrane (visceral and parietal layer) that is the piece of peritoneum that descended with testes into scrotal sac, superficial to tunica albiquinea
allows for easier movement of testes with scrotum

Question 47

seminiferous tubules

Answer 47

contains all stages of sperm development: spermatagonia, primary spermatocyte, secondary spermatocyte, spermatid, and sperm
supporting cells = sertoli cells (nurse cells)

Question 48

Leydig cells

Answer 48

exists in between tubules, secretes testosterone

Question 49

Sertoli cells

Answer 49

extends from basement membrane to lumen
forms blood-testis barrier
support developing sperm cells
produce fluid and control release of sperm into lumen
secrete inhibin, slows sperm production by inhibiting FSH
Support of spermiogenisis by surrounding and unfolding spermatids by providing nutrients and chemical stimuli that promote development
supports mitosis andmeiosis (promote division in response to FSH)
Blood testis barrier (similar to BBB)
essential for preserving differences between tubular fluid and interstitial fluid
prevents immune system from attacking spermatazoa

Question 50

Spermatogenesis

Answer 50

spermatagonia produces 2 kinds of daughter cells
Type A - remains outside blood-testis barrier and produce more daughter cells until death
Type B - differentiates into primary spermatocytes
(cells must pass through BTB to move inward towards lumen – new tight junction forms behind these cells)

Question 51

Spermatagonia

Answer 51

stem cells

Question 52

spermiogenesis

Answer 52

transformation of spermatagonia into spermatozoon (sprouts tail and discards cytoplasm to become lighter)
4 spermatids are formed, with each being haploid and unique
all four remain in contact with cytoplasmic bridge
accounts for synchronized release of sperm that are 50% x chromosome and 50% y chromosome
maturation of spermatid into sperm cells
changes that form spermatid into spermatazoa, discarding excess cytoplasm and growing tails

Question 53

Anatomy of sperm

Answer 53

head:
nucleus contains haploid set of chromosomes
acrosome contains hyaluronidase and proteinase enzymes that penetrate egg
tail:
midpiece contains mitochondria around flagella (produces ATP for flagellar movement)

Question 54

Puberty

Answer 54

surge of pituitary gonadotropins (LH, FSH) begins development
continues until first menstrual period or first ejaculation of viable sperm

Question 55

Brain-testicular axis

Answer 55

mature hypothalamus produces GnRH
stimulation of gonadotroph cells in anterior pituitary causes secretion of FSH and LH
Causes enlargement of secondary sexual organs
Testosterone sustains spermatogenesis throughout adulthood

Question 56

Controlling testosterone production

Answer 56

negative feedback system controls blood levels of testosterone
receptors in hypothalamus detects increase in blood level
secretion of GnRH slowed
anterior pituitary (FSH and LH) hormones slowed
Leydig cells of testes slowed
Blood level returns to normal

Question 57

Inhibin hormone

Answer 57

nurse cells release inhibin when you got enough sperm, inhibits FSH secretion by anterior pituitary and decreases sperm production

Question 58

Pathway of sperm flow through ducts of testis

Answer 58

seminiferous tubules
straight tubules
rete testis
efferent ducts
ductus epididymis
ductus (vas) deferens

Question 59

Spermatic ducts

Answer 59

efferent, epididymis, ductus deferens, and ejaculatory duct

Question 60

Epididymis

Answer 60

Head, body, and tail
6 m long coiled duct adhering to posterior of testis
site of sperm maturation and storage (fertile for 60 days)

Question 61

Efferent ducts

Answer 61

12 small ciliated ducts collecting sperm from rete testes and transporting it to the epididymis

Question 62

Ductus (vas) deferens

Answer 62

causes peristalsis during orgasm

muscular tube 45 cm long passing up from scrotum through inguinal canal to posterior surface of bladder

Question 63

Ejaculatory duct

Answer 63

2 cm duct formed from ductus deferens and seminal vesicle and passing through prostate to empty into urethra

Question 64

Pathway of Ductus Vas Deferens

Answer 64

Ascends along posterior border of epididymis
passes up through spermatic cord and inguinal ligament
reaches posterior surface of urinary bladder
empties into prostatic urethra with seminal vesicle
lined with pseudostratified columnar epithelium and covered with heavy coating along through peristaltic contractions

Question 65

Male urethra

Answer 65

8 inch long passageway for urine and semen
membranous urethra
Prostatic urethra (1 inch long)
membranous urethra (passes through UG diaphragm)
penile (spongy) urethra (through corpus spongiosum)

Question 66

Seminal vesicles

Answer 66

pair of pouchlike organs found posterior to base of bladder
filled with viscous fluid used to neutralize vaginal acid and male urethra, has fructose for ATP, prostaglandins to stimulate sperm motility and viability, and clotting proteins for coagulation of semen

Question 67

Prostate gland

Answer 67

single organ size of chestnut found inferior to bladder
secretes milky fluid that increases sperm motility and viability
citric acid for ATP production and enzymes for seminal liquefaction
enlarges with age

Question 68

Bulbourethral (Cowper’s) Gland

Answer 68

paired, pea-sized gland within UG diaphragm that secretes alkaline mucous into spongy urethra
neutralizes acids and lubricates

Question 69

Semen

Answer 69

60% seminal vesicle fluid, 30% prostatic, 10% spem

normal sperm count = 50-150 million/mL

Question 70

Cross section of penis

Answer 70

corpora cavernosa (upper paired, erectile tissue masses)
corpus spongiosum (lower erectile tissue mass that surrounds urethra)

Question 71

Life history of oogonia

Answer 71

born with 200,000 - 2 mill at birth, only 400 mature due to polar bodies
meiosis 1 resumes for the follicles prepping for ovulation so by the time they’re ready to ovulate it’s at meiosis 2
Sperm causes final stages of meiosis 2 to occur

Question 72

Follicular stages

Answer 72

Primordial, primary, secondary, tertiary (graafian), ovulation

Question 73

Primordial follicle

Answer 73

when oocyte is surrounded by single squamous layer of follicle cells
starting at puberty, these follicles are being continuously activated to be developed

Question 74

Granulosa cells

Answer 74

when follicular cells have enlarge, divided, and formed several layers around growing primary oocyte

Question 75

Zona pellucida

Answer 75

where granulosa cell and oocyte touch

Question 76

Thecal cells

Answer 76

adjacent cells that work together with granulosa to produce estrogen

Question 77

Secondary follicle

Answer 77

when follicular cells begin secreting small amounts of fluid that accumulates in small pockets –> gradually expands and separated inner and outer layers of follicle

Question 78

Corona radiata

Answer 78

granulosa cells attached to zona pellucida–still attached to oocyte at ovulation

Question 79

antrum

Answer 79

formed by granulosa cells secreting fluid

Question 80

Tertiary follicle

Answer 80

oocyte has reached metaphase of meiosis 2 and stopped developing; first polar body has been discarded

Question 81

Ovulation

Answer 81

Oocyte and corona radiata are ejected into the pelvic cavity

Oocyte is then moved into uterine tube by fimbriae

Question 82

Formation of corpus luteum

Answer 82

progesterone preps uterus for preg by stimulating maturation of uterine lining and secretions of uterine glands
(if no pregnancy: empty follicle collapses and ruptured blood vessels bleed into antrum; remaining granulosa cells invade area and proliferate)

Question 83

Formation of corpus albicans

Answer 83

marks end of ovarian cycle

fibroblasts invade corpus luteum and creates this structure

Question 84

uterine/fallopian tube

Answer 84

a narrow, 4 inch tube that extends from ovary to uterus
infundibulum is the opening near ovary (funnel shape) that has fimbriae (finger-like processes)
central region = ampulla
where it meets the uterus = isthmus

Question 85

Histology + function of uterine tube

Answer 85

mucosa, muscularis, and serosa

Functions – events occuring in uterine tube

Question 86

Overview of ovulation

Answer 86

fimbriae sweep oocyte into tube, cilia and peristalsis move it along, sperm reaches oocyte, fertilization occurs within 24 hours after ovulation, zygote reaches uterus about 7 days after ovulation

Question 87

Anatomy of uterus

Answer 87

Site of menstruation & development of fetus

subdivided into fundus,body, isthmus & cervix

Question 88

mucosa

Answer 88

ciliated columnar epithelium with secretory cells provide nutrients & cilia move along ovum

Question 89

muscularis

Answer 89

circular & longitudinal smooth muscle

peristalsis helps move ovum down to the uterus

Question 90

serosa

Answer 90

outer serous membrane

Question 91

histology of uterus

Answer 91

endometrium, myometrium, and perimetrium

Question 92

endometrium

Answer 92

simple columnar epithelium
stroma of connective tissue and endometrial glands
stratum functionalis
shed during menstruation
stratum basalis
replaces stratum functionalis each month

Question 93

myometrium

Answer 93

3 layers of smooth muscle

Question 94

perimetrium

Answer 94

visceral peritoneum

Question 95

blood supply to uterus

Answer 95

Uterine arteries branch as arcuate arteries and radial arteries that supply the myometrium
branches penetrate to the endometrium
spiral arteries supply the stratum functionalis
their constriction due to hormonal changes starts menstrual cycle

Question 96

endometriosis

Answer 96

growth of endometrial tissue outside uterus
can cover ovaries, outer surface of uterus, colon, kidneys, and bladder
Problem is tissue responds to hormonal changes by proliferating then breaking down & bleeding
causes pain, scarring & infertility

Question 97

Vagina

Answer 97

passageway for birth, menstrual flow, and intercourse
4 inch long fibromuscular organ ending at cervix
mucosal layer =
stratified squamous epithelium & areolar connective tissue
muscularis layer = smooth muscle allows considerable stretch
adventitia = loose connective tissue that binds it to other organs
lies between urinary bladder and rectum

Question 98

Female repro cycle

Answer 98

Controlled by monthly hormone cycle of anterior pituitary, hypothalamus & ovary
Monthly cycle of changes in ovary and uterus
Ovarian cycle
changes in ovary during & after maturation of oocyte
Uterine cycle
preparation of uterus to receive fertilized ovum
if implantation does not occur, the stratum functionalis is shed during menstruation

Question 99

Female puberty

Answer 99

9-10 in US
Triggered by rising levels of GnRH which stimulate anterior lobe of pituitary to produce FSH & LH (follicle-stimulating & luteinizing hormone)
FSH stimulates follicles to secrete estrogen & progesterone
2nd sex organs maturation,  in height & width of pelvis
prepares uterus for pregnancy
development of breasts
growth of pubic & axillary hair, apocrine & sebaceous glands
Menarche = first menstrual period (~age 12)
requires at least 17% body fat in teenager, 22% in adult
Female hormones secreted cyclically & in sequence

Question 100

Hormonal Regulation of Reproductive Cycle

Answer 100

GnRH secreted by the hypothalamus controls the female reproductive cycle
stimulates anterior pituitary to secrete FSH & LH
FSH initiates growth of follicles that secrete estrogen
estrogen maintains reproductive organs
LH stimulates ovulation & promotes formation of the corpus luteum which secretes estrogens, progesterone, relaxin & inhibin
progesterone prepares uterus for implantation and the mammary glands for milk secretion
relaxin facilitates implantation in the relaxed uterus
inhibin inhibits the secretion of FSH

Question 101

Sexual Cycle

Answer 101

Averages 28 days
Hormone cycle produces hierarchy of control
hypothalamus-> pituitary -> ovaries -> uterus
Follicular phase (2 weeks)
menstruation occurs during first 3 to 5 days of cycle
uterus replaces lost endometrium & follicles grow
Postovulatory phase (2 weeks)
corpus luteum stimulates endometrial thickening
endometrium lost again if pregnancy does not occur

Question 102

Menstrual Phase

Answer 102

Menstruation lasts for 5 days
First day is considered beginning of 28 day cycle
In ovary
20 follicles that began to develop 6 days before are now beginning to secrete estrogen
fluid is filling the antrum from granulosa cells
In uterus
declining levels of progesterone caused spiral arteries to constrict – glandular tissue dies
stratum functionalis layer is sloughed off along with 50 to 150 ml of blood

Question 103

Preovulatory Phase

Answer 103

Lasts from day 6 to 13 (most variable timeline)
In the ovary (follicular phase)
follicular secretion of estrogen & inhibin has slowed the secretion of FSH
dominant follicles survives to day 6
by day 14, graafian follicle has enlarged & bulges at surface
increasing estrogen levels trigger the secretion of LH
In the uterus (proliferative phase)
increasing estrogen levels have repaired & thickened the stratum functionalis to 4-10 mm in thickness

Question 104

Ovulation

Answer 104

Rupture of follicle & release of 2nd oocyte on day 14
Cause
increasing levels of estrogen stimulate release of GnRH which stimulates anterior pituitary to release more LH
Corpus hemorrhagicum results

Question 105

Postovulatory Phase

Answer 105

Most constant timeline = lasts 14 days
In the ovary (luteal phase)
if fertilization did not occur, corpus albicans is formed
as hormone levels drop, secretion of GnRH, FSH & LH rise
if fertilization did occur, developing embryo secretes human chorionic gonadotropin (hCG) which maintains health of corpus luteum & its hormone secretions
In the uterus (secretory phase)
hormones from corpus luteum promote thickening of endometrium to 12-18 mm
formation of more endometrial glands & vascularization
if no fertilization occurs, menstrual phase will begin

Question 106

Breasts

Answer 106

Mound of tissue overlying the pectoralis major
axillary tail in armpit contains many lymphatic vessels
Nipple is surrounded by areola (colored zone)
melanocytes
smooth muscle contracts wrinkling the skin & erecting the nipple in response to cold, touch
Suspensory ligaments attach it to skin & muscle
If nonlactating, contains little glandular tissue just a system of branching ducts and fat tissue

Question 107

Mammary Glands

Answer 107

Modified sweat glands that produce milk (lactation)
amount of adipose determines size of breast
milk-secreting glands open by lactiferous ducts at the nipple

Question 108

Development of mammary glands

Answer 108

Lactation = synthesis and ejection of milk from mammary glands
High estrogen levels in pregnancy cause ducts to grow and branch
Progesterone stimulates budding & development of the acini at the ends of the ducts

Question 109

Colostrum & Milk Synthesis

Answer 109

Colostrum forms in late pregnancy
similar to breast milk but contains 1/3 less fat, thinner
nutrition for first 1 to 3 days after birth
contains IgA protection from gastroenteritis
Synthesis is promoted by prolactin (from pituitary)
synthesis of hormone begins 5 weeks into pregnancy, by full term it is 20x normal level
steroid hormones from placenta oppose it until birth
At birth, prolactin secretion drops to nonpregnant levels, but  20 times with nursing events
without continuous nursing, production stops in 1 week
Only 5-10% of women become pregnant again while nursing
inhibition of GnRH & reduced ovarian cycling
Without continuous nursing decreased prolactin levels allow normal ovarian cycling

Question 110

milk ejection + milk letdown

Answer 110

controlled by a neuroendocrine reflex
infant’s suckling stimulates sensory receptors in nipple, signaling the hypothalamus & posterior pituitary to release oxytocin
oxytocin stimulates myoepithelial cells
Myoepithelial cells surround each gland acinus
epithelial cells packed with actin
contract like smooth muscle to squeeze milk into duct
milk flow within 30-60 seconds after suckling begins

Question 111

Breast milk

Answer 111

Colostrum & milk have a laxative effect that clears intestine (green, bile-filled fecal material in newborn)
Breast milk supplies antibodies & helps to colonizes intestine with beneficial bacteria
Nursing woman can produce 1.5L per day
inc calorie intake by 300, inc Ca+2 & vitamin D

Question 112

benefits of breast feeding

Answer 112

Faster & better absorption of the “right” nutrients

Decreased incidence of diseases later in life
reduction in allergies, respiratory & GI infections, ear infections & diarrhea

Parent-child bonding

Infant in control of intake

Question 113

aging female repro system

Answer 113

Hormone-directed sexual characteristics start to develop at puberty
Reproductive cycle occurs once/month from menarche (10-14) until menopause (between 40 & 50)
Fertility declines with age
decreasing number of viable eggs
less frequent ovulation
declining ability of uterus to support embryo
Menopause is cessation of menstruation
no remaining follicles to stimulate estrogen secretion
osteoporosis, hot flashes, mood swings, organ atrophy

Question 114

Aging male repro system

Answer 114

Decline in reproductive function is more subtle (capacity may remain into 90’s)
Decline in testosterone at 55
reduced muscle synthesis
fewer viable sperm
reduced sexual desire
Enlargement of prostate (benign hyperplasia)
1/3 of males over 60
frequent urination, decreased force of stream