Exam 2 Flashcards

Question 1

Q

How many pairs of cranial nerves are there?

Question 2

Q

What are cranial nerves I and II connected to?

Answer

A

The cerebrum

Question 3

Q

What are cranial nerves III-XII connected to?

Answer

A

The brain stem

Question 4

Q

Which portion of the nervous system is the optic nerve considered to be a part of?

Answer

A

The central nervous system

Question 5

Q

Which portion of the nervous system are all cranial nerves (other than the optic nerve) a part of?

Answer

A

The peripheral nervous system

Question 6

Q

What do the afferent neurons in cranial nerves do?

Answer

A

Transmit sensory information to the brain or brain stem.

Question 7

Q

What is cranial nerve II (optic nerve) responsible for? What type of nerve is it?

Answer

A

Vision, sensory nerve

Question 8

Q

What does cranial nerve VIII (vestibulocochlear nerve) responsible for?What type of nerve is it?

Answer

A

Balance and hearing, sensory nerve

Question 9

Q

What is cranial nerve I (olfactory nerve) responsible for? What type of nerve is it?

Answer

A

Smell, sensory nerve

Question 10

Q

Cranial nerves can contain _____, ___________, and ________ neurons that control effector tissues.

Answer

A

somatic, parasympathetic, sympathetic

Question 11

Q

What is cranial nerve III (oculomotor nerve) responsible for? What type of nerve is it?

Answer

A

Extraocular eye muscle movement, motor nerve

Question 12

Q

What is cranial nerve XII (hypoglossal nerve) responsible for? What type of nerve is ti?

Answer

A

Muscles of tongue; motor nerve

Question 13

Q

What does cranial nerve I (olfactory nerve) arise from?

Answer

A

The olfactory bulb

Question 14

Q

What does cranial nerve II (optic nerve) arise from?

Answer

A

The diencephalon

Question 15

Q

What does cranial nerve III (oculomotor nerve) arise from?

Answer

A

The midbrain

Question 16

Q

What does cranial nerve VIII (vestibulocochlear nerve) arise from?

Answer

A

The medulla

Question 17

Q

What does cranial nerve X (vagus nerve) arise from?

Answer

A

The medulla

Question 18

Q

What does cranial nerve XII (hypoglossal nerve) arise from?

Answer

A

The medulla

Question 19

Q

What is the nictitating membrane?

Answer

A

A third eyelid, mostly found in birds

Question 20

Q

What does the granula iridica do? Where is it found and in what animal is it most commonly seen in?

Answer

A

It reduces glare and increases visual clarity, found in the eye around the pupil, most commonly seen in horses

Question 21

Q

What part of the eye makes a cat’s eye glow?

Answer

A

The tapetum lacidum

Question 22

Q

What does the suspensory ligament of the eye do?

Answer

A

It connects the ciliary body with the lens, holding it in place.

Question 23

Q

What is the ciliary body of the eye?

Answer

A

A circular structure that is an extension of the iris

Question 24

Q

What is the iris of the eye?

Answer

A

The colored portion around the pupil

Question 25

Q

What is the pupil of the eye?

Answer

A

The opening at the center of the iris through which light passes

Question 26

Q

What is the lens of the eye?

Answer

A

A curved structure in the eye that bends light and focuses it for the retina (located behind the pupil and iris)

Question 27

Q

What is the cornea of the eye?

Answer

A

The outer layer at the front of the eye

Question 28

Q

What is the aqueous humor of the eye?

Answer

A

The clear liquid inside the front of the eye

Question 29

Q

What is the vitreous humor of the eye?

Answer

A

A clear, colorless fluid that fills the space between the lens and the retina

Question 30

Q

What is the optic disc of the eye?

Answer

A

The round spot on the retina formed by the passage of the axons of the retinal ganglion cells. Where the retina and optic nerve connect.

Question 31

Q

Why is there an optic disc blind spot?

Answer

A

The point where the optic nerves converge to exit the eye (the optic disc). This area of the eye has no light-sensitive cells. This results in a break in the visual field.

Question 32

Q

What is the sclera of the eye?

Answer

A

The white of the eye. A protective covering that wraps over most of the eyeball.

Question 33

Q

What is the retina of the eye?

Answer

A

A layer of photoreceptor cells and glial cells within the eye that captures incoming photons and transmits them along neuronal pathways.

Question 34

Q

What is the choroid of the eye?

Answer

A

The layer of blood vessels and connective tissue between the sclera and the retina.

Question 35

Q

What type of muscle in the iris controls pupil dilation? What is the name of the muscle?

Answer

A

Smooth muscle, ciliary muscle

Question 36

Q

What portion of the nervous system controls pupillary constriction?

Answer

A

The parasympathetic nervous system

Question 37

Q

What muscle (other than smooth) controls pupillary constriction?

Answer

A

Circular muscle

Question 38

Q

What portion of the nervous system controls pupillary dilation?

Answer

A

The sympathetic nervous system

Question 39

Q

What muscle (not smooth) controls pupillary dilation?

Answer

A

Radial muscle

Question 40

Q

What does changes in cornea shape cause?:

Answer

A

Visual impairment

Question 41

Q

What are the components of the retina?

Answer

A

Fibers of the optic nerve, ganglion cells, amacrine cells, bipolar cells, horizontal cells, cone and rod cells (photoreceptor cells), pigment layer, choroid layer, and sclera

Question 42

Q

What do rod cells do?

Answer

A

Provide light vision

Question 43

Q

What are the characteristics of rod cells?

Answer

A

Rhodopsin photopigment absorbs all wavelengths of light, more sensitive but cannot distinguish color, results in shades of gray based on light intensity

Question 44

Q

What do cone cells do?

Answer

A

Provide color vision

Question 45

Q

What are the characteristics of cone cells?

Answer

A

Three types in primates with different scotopsin proteins; scotopsin photopigment can detect red, green, and blue wavelengths

Question 46

Q

How does information from rod and cone cells reach the optic nerve?

Answer

A

Light reduces rod and cone cell neurotransmitter release

Question 47

Q

Where does light hit in the eye for someone who is nearsighted?

Answer

A

Before the retina

Question 48

Q

Where does light hit in the eye for someone who is far sighted?

Answer

A

After the retina

Question 49

Q

How does light hit in the eye for someone who has astigmatism?

Answer

A

The light is scattered on and around the retina

Question 50

Q

What does the vestibular apparatus contribute to?

Answer

A

Sense of balance

Question 51

Q

What portion of the ear are semicircular canals located in?

Answer

A

The vestibular apparatus

Question 52

Q

What do semicircular canals do?

Answer

A

Detect changes in head position and rotational or angular acceleration of the head.

Question 53

Q

Which structures are included in the otolith organs?

Answer

A

The utricle and saccule

Question 54

Q

What do otolith organs do?

Answer

A

Detect changes in head position and linear acceleration of the head

Question 55

Q

What provides positioning information?

Answer

A

Movement of fluid over hair cells

Question 56

Q

What type of receptor are hair cells?

Answer

A

Mechanoreceptors

Question 57

Q

How is information transmitted from the ear to the brain?

Answer

A

Through the vestibulocochlear nerve (VIII) to the cerebellum.

Question 58

Q

What are the hairs of hair cells in the ear called?

Answer

A

Kinocilium and stereocilia

Question 59

Q

What connects to hair cells in the ear?

Answer

A

Vestibular nerve fibers

Question 60

Q

What are the bands between stereocilium called?

Answer

A

Tip links

Question 61

Q

What are the steps of depolarization of hair cells in semicircular canals?

Answer

A

1) Tip links stretch and open channels when stereocilia bend towards tallest member.
2) K+ enters hair cell, depolarizing it.
3) Depolarization opens voltage gated Ca^2+ channels.
4) Ca^2+ entry causes greater release of neurotransmitter.
5) More neurotransmitters leads to higher rate of action potential.

Question 62

Q

What are the steps of hyperpolarization of hair cells in semicircular canals?

Answer

A

1) Tip links slacken and close when stereocilia bend away from the tallest member.
2) No K+ enters cell, hyperpolarizing it.
3) Ca^2+ channels close
4) No neurotransmitter is released .
5) No action potentials occur.

Question 63

Q

What do otoliths do?

Answer

A

Provide weight to fluid overlaying hair cells.

Question 64

Q

What structures are included in the otolithic membrane?

Answer

A

Otoliths and a gelatinous layer

Answer 64

A

The eardrum

Answer 65

A

The middle ear of mammals

Answer 66

A

Vibrates in response to sound waves and provides sound intensity and pitch information.

Answer 67

A

Wave amplitudes

Answer 68

A

Wave frequency

Answer 69

A

High frequency; 20,000 Hz; travels short distances

Answer 70

A

Low frequency; 20 Hz; travels through land and water over long distances

Answer 71

A

Whales and elephants

Answer 72

A

Three small bones in mammals that transfer vibrations from the tympanic membrane to the cochlea oval window.

Answer 73

A

Tympanic membrane —> malleus —> incus —> stapes —> oval window

Answer 74

A

Columella

Answer 75

A

A coiled tubular system with three fluid filled compartments

Answer 76

A

Scala vestibuli

Answer 77

A

Scala media or cochlear duct

Answer 78

A

Scala tympani

Answer 79

A

Thousands of hair cells arranged in four parallel rows found on top of the basilar membrane in the cochlear duct.

Answer 80

A

A sense of hearing

Answer 81

A

Inner row of hair cells transform cochlear vibrations into action potentials that are then transmitted to the brain temporal lobe by cranial nerve VIII.

Answer 82

A

A membrane covering the entrance to the cochlea in the inner ear.

Answer 83

A

One of the two openings into the cochlea from the middle ear. Serves to decompress acoustic energy that enters the cochlea.

Answer 84

A

A hammer-shaped bone that connects to the tympanic membrane.

Answer 85

A

Anvil-shaped bone that connects to the malleus and the stapes.

Answer 86

A

Stirrup-shaped (smallest bone in the body) bone that connects to the incus and the oval window.

Answer 87

A

A fluid-filled, spiral-shaped cavity found in the inner ear.

Answer 88

A

The main mechanical element of the inner ear. It separates incoming sounds into its component frequencies that activate different cochlear regions.

Answer 89

A

A highly hydrated matrix above hair cells in the cochlea. Plays a vital role in stimulation of hair cells.

Answer 90

A

Through fluid (perilymph) within the scala vestibuli and then the scala media (cochlear duct) over the organ of corti.

Answer 91

A

Different sound wave frequencies cause peak vibrations at different positions along the basilar membrane.

Answer 92

A

Greater sound wave amplitudes cause greater basilar membrane movement.

Answer 93

A

The cerebrum temporal lobe

Answer 94

A

The stereocilia of the basilar membrane contact the overlying tectorial membrane. The hairs are bent when the basilar membrane is deflected in relation to the tectorial membrane. The bending of the hair cell opens mechanically gates channels.

Answer 95

A

A type of chemoreceptor found in the tongue taste buds that prove a sense of taste.

Answer 96

A

Food molecules bind to receptors in gustatory cells that trigger cell action potentials. Action potential are sent via cranial nerve VII and X to the cerebrum parietal and temporal lobes and the hypothalamus.

Answer 97

A

Bitter, sweet, sour, or salty foods.

Answer 98

A

Channels or 7TMDR

Answer 99

A

A type of chemoreceptor found in the nasal cavity (believed to be the only type of neuron in mammals to undergo mitosis during adult life)

Answer 100

A

1 trillion

Answer 101

A

Odor present
Nostrils
Respiratory epithelium in the nasal passage
Olfactory epithelium
Olfactory bulb
Brain

Answer 102

A

Pheromones present
The moth of the vomeronasal channel
Vomeronasal organ (Jacobson’s organ)
Impulse transmitted
Olfactory bulb
Brain

Answer 103

A

On mitral cells in olfactory glomeruli

Answer 104

A

“Smell collection centers” where neurons for a specific odor molecule converge on mitral cells

Answer 105

A

increase, neurotransmitters

Answer 106

A

Send sensory information to cerebrum temporal lobe.

Answer 107

A

An addition sense organ in mammals and reptiles. Causes reproductive and social behaviors by reception of pheromones.

Answer 108

A

The hypothalamus (region of the brain that controls reproduction)

Answer 109

A

Animal opening of VNO to receive pheromones

Answer 110

A

A system of glands or tissues that secrete hormones into the blood and regulate animal homeostasis and physiology.

Answer 111

A

The study of endocrine glands, their secretion of hormone into the blood, and the effects of endocrine hormones on tissues.

Answer 112

A

The endocrine system provides a slower rate of change - typically seconds, days, or weeks.

Answer 113

A

growth, reproduction, stress

Answer 114

A

Pineal, hypothalamus, pituitary, parathyroid, thyroid, thymus, heart, liver, stomach, adrenal gland, pancreas, duodenum, kidney, adipose tissue, skin, ovaries, and placenta

Answer 115

A

maintain animal temperature
food, water, and mineral seeking and satiety
water, ion, and pH balance
digestion, metabolism, and growth
behavior and stress response
biological rhythms
reproduction

Answer 116

A

An increase in the size of an organ to compensate for the activity of the other lost organ.

Answer 117

A

Arnold Bethold’s cockerel experiment

Answer 118

A

Cells with receptors for the specific hormone

Answer 119

A

The time it takes for half of a hormone concentration in blood to disappear.

Answer 120

A

Hormone metabolism

Answer 121

A

Basal or tonic, sustained, and episodic.

Answer 122

A

The hormone is secrete in low constant concentrations

Answer 123

A

The hormone is secreted in high constant concentrations

Answer 124

A

The hormone is secreted in pulses or episodes

Answer 125

A

Common for neuroendocrine hormones, pulses are related to neuron action potentials

Answer 126

A

In the liver, kidneys, or lungs

Answer 127

A

Blood, urine, or feces.

Answer 128

A

When the hormone reduces or turns off its own production

Answer 129

A

When the hormone tends to increase its own production

Answer 130

A

When rapid or drastic change is needed

Answer 131

A

Parturition

Answer 132

A

The hypothalamus and the pituitary gland

Answer 133

A

Two distinct glands- the anterior and posterior pituitary

Answer 134

A

Groups of nerve cell bodies that respond to specific sensory information and release neuroendocrine hormones into the anterior or posterior pituitary.

Answer 135

A

Ventromedial nuclei (VMN)
Arcuate nuclei (ARC)
Anterior hypothalamic area (AHA)
Preoptic nuclei (PON)
Suprachiasmatic nuclei (SCN)
Paraventricular nuclei (PVN)
Supraoptic nuclei (SON

Answer 136

A

From oral tissue

Answer 137

A

From brain/neural tissue

Answer 138

A

Oxytocin and vasopressin

Answer 139

A

Stimulates milk ejection and uterine contractions in females.

Answer 140

A

Contributes to animal water retention and regulates blood pressure.

Answer 141

A

A peptide (8 amino acids)

Answer 142

A

It increases the permeability of distal and collecting tubules to water.

Answer 143

A

It causes vasoconstriction.

Answer 144

A

Contraction of muscle in the uterus for parturition.

Answer 145

A

Contraction of smooth muscle in mammary glands for milk ejection.

Answer 146

A

Animal behavior including mate choice and pair bonding, trust, mothering abilities, and orgasms.

Answer 147

A

Fetus presses on cervix
Sensory neurons in cervix send information to the hypothalamus
Oxytocin is released from posterior pituitary
Oxytocin stimulates uterine smooth muscle contraction
Fetus presses on cervix more vigorously - contributes to labor and parturition.

Answer 148

A

Labor induction

Answer 149

A

Stimulation of neurons within the mammary gland during nursing.
Information sent to the hypothalamus
Oxytocin is released from the posterior pituitary
Oxytocin stimulates contraction of myoepithelial cells surrounding glandular cells
Milk is transported into mammary gland ducts and cistern.

Answer 150

A

Peptide (8 amino acids)

Answer 151

A

Anti-diuretic hormone (ADH), Arginine vasopressin (AVP) in humans and other animals, Lysine vasopressin (LVP) in pigs

Answer 152

A

AVP binds to receptors (V1R) on smooth muscle cells around arteries causing vasoconstriction, arterial resistance, and elevated blood pressure.

Answer 153

A

AVP binds V2R in kidney, increases aquaporin activity, increases animal water retention and reduces urine volume.

Answer 154

A

Increased blood volume and blood pressure.

Answer 155

A

When the body cannot properly balance fluid levels due to damage of the pituitary gland or hypothalamus from surgery, a tumor, head injury, or illness.

Answer 156

A

A mutation on the vasopressin gene.

Answer 157

A

Excessive drinking

Answer 158

A

Excessive urination

Answer 159

A

Allows small quantities of neuroendocrine hormone to act on cells in the anterior pituitary before they are diluted by general circulation.

Answer 160

A

Lactotropes and somatotropes

Answer 161

A

Gonadotropes or thyrotropes

Answer 162

A

Corticotropes

Answer 163

A

Secrete releasing and inhibiting neuroendocrine hormones into portal system

Answer 164

A

Trope cells

Answer 165

A

Stimulates mammary gland growth and production of milk factors in alveolus, particularly milk proteins casein and lactalbumin.

Answer 166

A

Lactotrope cells in the anterior pituitary.

Answer 167

A

negative regulation, dopamine

Answer 168

A

Mechanoreceptors in teats and reduces dopamine release from hypothalamus, increasing release of prolactin from anterior pituitary.

Answer 169

A

PRL receptors

Answer 170

A

Synthesize and secrete milk proteins in response to PRL

Answer 171

A

The most common type of pituitary tumor. Causes hyperprolactinemia or excessive prolactin secretion.

Answer 172

A

Can cause infertility in females and males. In males it can lead to erectile dysfunction and low libido.

Answer 173

A

Abnormal mammary secretions, can occur in males.

Answer 174

A

Dopamine agonists

Answer 175

A

Skin, tumors/cancers, and sweat glands.

Answer 176

A

Female reproduction, sodium and water balance, metabolism, and behavior.

Answer 177

A

Prolactin

Answer 178

A

Secrete growth hormone (GH) (aka somatotropin) from the anterior pituitary

Answer 179

A

Somatotropes

Answer 180

A

Neuroendocrine hormone growth hormone releasing hormone (GHRH)

Answer 181

A

Within hypothalamus arcuate nucleus (ARC)

Answer 182

A

Neuroendocrine hormone growth hormone inhibitory hormone (GHIH) (aka somatostatin)

Answer 183

A

Within hypothalamus periventricular nucleus (PVN)

Answer 184

A

Various tissues, particularly the liver, skeletal muscle, adipose tissue, bone, and cartilage (osteoblasts/chondrocytes)

Answer 185

A

Causes liver to release glucose and lipolysis of adipose tissue to release triglycerides into the blood for energy. Occurs during animal fasting, exercise, and hibernation.

Answer 186

A

Acute or immediate actions

Answer 187

A

Increases chondrocyte and osteoblast activity, resulting in bone growth. Increases skeletal muscle fiber synthesis and hypertrophy.

Answer 188

A

Chronic or long-term actions

Answer 189

A

IGF-1 and IGF-2

Answer 190

A

GH or IGF-1/IGF-2

Answer 191

A

IGF-1, GH

Answer 192

A

GH, IGF-1

Answer 193

A

High levels of circulating GH and IGF-1 as a child that results in abnormal bone lengthening. Typically caused by pituitary tumors.

Answer 194

A

High levels of circulating G and IGF-1 during middle age that increases bone diameter.

Answer 195

A

Insensitivity to GH, resulting in abnormal short stature. Typically caused by recessive mutation of the GH receptor (GHR) gene.

Answer 196

A

Robert Wadlow

Answer 197

A

Maurice Tillet

Answer 198

A

Norman Apolo Ramirez

Answer 199

A

Major reduction of pro-aging signaling, cancer, and diabetes in humans.

Answer 200

A

A mutation in the GH gene.

Answer 201

A

A single IGF-1 allele.

Answer 202

A

Pituitary extracts from human cadavers. Side effects included a prion disease called Creutzfeld-Jakob disease.

Answer 203

A

Genetech began producing recombinant human GH that was produced by the FDA for use in children with growth deficiency. Marketed as protropin.

Answer 204

A

In 1937, pituitary extracts. In1994, recombinant bovine growth hormone (bGH or BST). Increases milk production by about 10 lbs/day

Answer 205

A

Salmon with transgenic GH. Fist transgenic animal approved for human consumption in the US.

Answer 206

A

They have a GH gene from a closely related species (chinook) and a gene promotor from another type of fish that allows production of the chinook GH from all tissues year around. Reduced market tie from 3 years to 18 months.

Answer 207

A

18 months

Answer 208

A

To reduce hunting of wild salmon and increase food availability.

Answer 209

A

Adrenocorticotropic hormone (ACTH)

Answer 210

A

The neuroendocrine hormone corticotropin releasing hormone (CRH)

Answer 211

A

Within hypothalamus periventricular nuclei (PVN)

Answer 212

A

An outer cortex and inner medulla region.

Answer 213

A

Cranial to the kidneys

Answer 214

A

Mineralocorticoids, glucocorticoids, and androgens

Answer 215

A

Aldosterone

Answer 216

A

Chromaffin, epinephrine, norepinephrine

Answer 217

A

zona fasciculata, ACTH, cortisol, ACTH

Answer 218

A

Zona glomerulosa

Answer 219

A

Zona fasciculata

Answer 220

A

Zona reticularis

Answer 221

A

A connective tissue capsule

Answer 222

A

Zona glomerulosa, zona fasciculata, zona reticularis

Answer 223

A

During stress, fasting, and in the morning hours

Answer 224

A

zona fasciculata, cortisol

Answer 225

A

Steroid nuclear receptors

Answer 226

A

In the liver, adipose tissue, skeletal muscle, and immune cells.

Answer 227

A

gene transcription, transcription

Answer 228

A

Increase animal blood glucose concentrations during stress and fasting, increase lipolysis in adipose tissue and proteolysis in skeletal muscle, block some immune processes, block some reproductive processes, reduce digestive tract activity, and fetal cortisol helps initiate parturition and promote fetal lung development.

Answer 229

A

By increasing glucose synthesis (gluconeogenesis) and release from the liver.

Answer 230

A

It frees triglycerides and amino acids as additional sources of energy.

Answer 231

A

Thyroid stimulating hormone (TSH)

Answer 232

A

Thyrotropin releasing hormone (TRH)

Answer 233

A

Within hypothalamus periventricular nuclei (PVN)

Answer 234

A

Next to the trachea

Answer 235

A

principle, T3, T4

Answer 236

A

5’ 3’ deiodinase

Answer 237

A

To a nuclear receptor inside the target cell, regulates gene transcription

Answer 238

A

On thyroglobulin

Answer 239

A

A large protein in the thyroid follicle colloid

Answer 240

A

Increase animal metabolic activity and thermogenesis, contributes to CNS development in fetus, and increases receptors for many other hormone (including GH) and promotes animal growth.

Answer 241

A

An under active thyroid gland. A reduction or loss of thyroid hormone production.

Answer 242

A

Sensitivity to cold, adiposity (fat accumulation), depression, and impaired memory.

Answer 243

A

Iodine deficiency

Answer 244

A

An abnormal enlargement of the thyroid gland?

Answer 245

A

No iodine = no T3 and T4 = no negative feedback on TRH/TSH. Excessive TSH causes thyroid gland growth.

Answer 246

A

An autoimmune disease where the immune system attacks. thyroglobulin, causing inflammation and swelling of the thyroid gland.

Answer 247

A

Maternal iodine deficiency and hypothyroidism

Answer 248

A

Parathyroid gland chief cells and thyroid gland C cells.

Answer 249

A

Causes chief cells to release PTH which then increases bone osteoclast activity and release of calcium and phosphate from animal bone.

Answer 250

A

Parathyroid hormone

Answer 251

A

Increases vitamin D production in kidney which helps to increase dietary calcium absorption from the digestive tract.

Answer 252

A

Causes C cells in thyroid gland to release calcitonin, which inhibits osteoclast activity.

Answer 253

A

Reduced calcium in diet or reduced calcium absorption from digestive tract, leading to an increase in blood PTH and bone degeneration.

Answer 254

A

5ft long, 4ft wide, 5ft tall, and over 400 lbs (640 times bigger than a human heart)

Answer 255

A

The heart and blood vessels or vasculature

Answer 256

A

water; solutes or ions; glucose, triglycerides, and amino acids; large proteins; endocrine hormones; cells/cellular material; gases, oxygen; and carbon dioxide; heat

Answer 257

A

In the pericardial cavity, located in an area called the mediastinum

Answer 258

A

The inside connective tissue of the pericardium, touching the heart.

Answer 259

A

The space between the visceral pericardium and the parietal pericardium.

Answer 260

A

The outside lining of the pericardium, away from the heart.

Answer 261

A

It collects oxygen depleted blood from tissues and pumps it to the lungs

Answer 262

A

It collects oxygen-rich blood from the lungs and pumps it to body tissues.

Answer 263

A

Collects blood entering the heart

Answer 264

A

Forces blood out of the heart.

Answer 265

A

Returns blood from the head and upper limbs

Answer 266

A

Return blood from the right lung

Answer 267

A

Returns blood from the lower body and legs

Answer 268

A

Return blood from the left lung

Answer 269

A

Carry blood away from the heart

Answer 270

A

right ventricle, pulmonary artery

Answer 271

A

left ventricle, aorta

Answer 272

A

Carry blood to the heart

Answer 273

A

right atrium, vena cava

Answer 274

A

left atrium, pulmonary veins

Answer 275

A

Ensure blood flow from atria into ventricles

Answer 276

A

semilunar

Answer 277

A

Pressure in the atrium is not much greater than venous pressure.

Answer 278

A

Tricuspid

Answer 279

A

Bicuspid/ mitral

Answer 280

A

Chordae tendineae and valve leaflets

Answer 281

A

opens, closes

Answer 282

A

Between the endocardium and the visceral pericardium

Answer 283

A

Myocardiocytes arranged in a spiral pattern

Answer 284

A

When they contract, they “wring” blood from the apex to the base where the major arteries exit

Answer 285

A

Desmosomes and gap junctions

Answer 286

A

They allow the spread of action potential between myocardiocytes throughout the myocardium.

Answer 287

A

Pacemaker cells

Answer 288

A

A special conductivity cell found in the cardiac muscle, generate spontaneous action potentials that spread throughout myocardiocyte gap junctions

Answer 289

A

Heart contraction, heart blood ejection

Answer 290

A

Heat relaxation, heart blood filling

Answer 291

A

In the sinoatrial node (SA) and the atrioventricular node (AV)

Answer 292

A

They do not have a resting membrane potential, and they slowly depolarize until reaching threshold.

Answer 293

A

The opening of a voltage gated calcium channel, allowing calcium to enter the cell.

Answer 294

A

Autonomic neurons synapse on SA node and modify pacemaker cell activity

Answer 295

A

Secondary group of pacemaker cells activated by the SA node and located in the heart septum

Answer 296

A

To help transmit action potentials between atria and ventricles

Answer 297

A

It allows the atria to completely contract and fill ventricle with blood before the next depolarization.

Answer 298

A

Pacemaker cells located in the heart septum that transmit action potential from the AV node into purkinje fibers.

Answer 299

A

Elongated myocardial cells that form branches and rapidly propagate action potentials throughout the ventricle myocardium.

Answer 300

A

conductivity, contraction

Answer 301

A

Have a delay in reestablishment in resting membrane potential. Near peak of action potential, voltage gated calcium channels open letting more positive charge into the cell.

Answer 302

A

It creates a delay between heart contractions so that tetany doe not occur.

Answer 303

A

Electrocardiogram (ECG or EKG)

Answer 304

A

Abnormal heart electrical activity, abnormal heart rate and rhythm

Answer 305

A

An irregular and often rapid heart rhythm

Answer 306

A

Atrial depolarization

Answer 307

A

Ventricular depolarization

Answer 308

A

Ventricular repolarization

Answer 309

A

AV nodal delay, time it takes for electrical conductivity to move between atria and ventricles.

Answer 310

A

The time between ventricle depolarization and repolarization, when ventricular contraction occurs.

Answer 311

A

Passive ventricular filling, all chambers at rest.

Answer 312

A

One complete cycle of heart contraction

Answer 313

A

Passive filling during ventricular and atrial diastole.
Atrial contraction
Isovolumetric ventricular contraction
Ventricular ejection
Isovolumetric ventricular relaxation

Answer 314

A

A phonocardiogram

Answer 315

A

Shutting of the AV (LUB or heart sound S or S1) and semilunar (DUB or S2) valves during systole.

Answer 316

A

An abnormal heart sound that typically results from abnormal heart valve function.

Answer 317

A

Heart murmurs that are common in young but disappear in adulthood.

Answer 318

A

AV valves are open and aortic and pulmonary valves are closed. Blood flows from the vena cava and pulmonary veins into atria and into ventricles by passive filling.

Answer 319

A

Ventricular filling of blood is completed.

Answer 320

A

End-diastolic volume

Answer 321

A

SA nodes fire, atria depolarize (P wave) and contract, increasing atrial pressure. Impulse passes through AV node and bundle of His, depolarizing ventricles (QRS complex). Ventricles contract, increasing ventricular pressure and AV nodes close.

Answer 322

A

Both AV and semilunar valves are closed, and ventricles continue to contract. Ventricular pressure rapidly build but volume doesn’t change. When ventricular pressure exceeds pulmonary artery and aorta pressure, pulmonary and aortic semilunar valves open. Blood is forced into pulmonary artery and aorta and ventricular volume decreases rapidly.

Answer 323

A

Ventricular emptying is completed.

Answer 324

A

End-systolic volume

Answer 325

A

The volume of blood pumped out of the ventricles.

Answer 326

A

Ventricles repolarize (T wave), ventricular pressure falls below arterial blood pressure and aortic and pulmonary semilunar valves close (ventricular repolarization). Ventricular pressure continues to fall (isovolumetric ventricular relaxation).

Answer 327

A

The number of cardiac cycles per minutes.

Answer 328

A

The volume of blood ejected or pumped by the heart per minute.

Answer 329

A

Heart rate x stroke volume

Answer 330

A

Animal activity, autonomic nervous system, animal size, body temperature, and animal age.

Answer 331

A

A balance between the parasympathetic and sympathetic nervous system

Answer 332

A

ACh decreases heart rate through decreased SA node activity and increased AV node delay

Answer 333

A

NE and E increases heart rate through increased SA node activity and decreased nodal delay.

Answer 334

A

They contract smooth muscle around veins, forcing more blood back into the right side of the heart. They also increase myocardiocyte contraction, squeezing more blood into the ventricle. This results in greater EDV and greater SV.

Answer 335

A

The more that myocardiocytes are stretched at EDV, the stronger they contract and the greater the SV.

Answer 336

A

The stretching of myocardiocytes results in increased tension and causes thick and thin myofilaments to be closer resulting in more cross bridge interactions.

Answer 337

A

The potential force generated within the ventricle wall due to cardiac stretch.

Answer 338

A

It increases the contraction capacity of the cardiac muscle, allowing for greater blood ejection from the ventricle when a larger volume is present.

Answer 339

A

Ventricular filling and EDV

Answer 340

A

The force against which the heart must contract to eject blood out of the semilunar valves, particularly the aortic valve.

Answer 341

A

Arterial blood pressure

Answer 342

A

It allows the two sides of the heart equilibrate and eject an equal volume of blood.

Answer 343

A

Providing tissues with blood, oxygen, and nutrients; overcoming gravity and driving blood to the brain; providing proper blood flow to the heart; and providing blood filter pressure on the kidneys.

Answer 344

A

Cardiac output, blood vessel radius, and animal blood volume.

Answer 345

A

Arteries, arterials, capillaries, venules, and veins

Answer 346

A

Simple squamous epithelium, connective tissues (inner layer)

Answer 347

A

An internal elastic layer and an external elastic layer

Answer 348

A

Smooth muscle (thicker in arteries and arterioles) and elastic fibers

Answer 349

A

Connective tissue, callogen fibers

Answer 350

A

Provide rapid passage of blood from heart to tissues

Answer 351

A

They expand during systole and recoil during diastole (because if a thick external elastic membrane)

Answer 352

A

The pressure on arteries during systole is 120 mmHg and the pressure on arteries during diastole is 80 mmHg.

Answer 353

A

Average of blood pressure generated during a single cardiac cycle. Measure of the driving force of blood through the cardiovascular system.

Answer 354

A

Systole pressure + (2 x diastole pressure)/3

Answer 355

A

It would overwork the heart and create vessel damage.

Answer 356

A

Arteriole total peripheral resistance (TPR)

Answer 357

A

Regulate MAP by controlling total peripheral vascular resistance (TPR) or the resistance of blood flow

Answer 358

A

Smooth muscle contraction or relaxation in arterioles

Answer 359

A

Vasular tone

Answer 360

A

Myogenic activity and persistent sympathetic stimulation.

Answer 361

A

higher, lower

Answer 362

A

A type of autoregulation that causes increased myogenic activity and vasoconstriction.

Answer 363

A

Smooth muscle relaxation triggered by reduced oxygen or increased carbon dioxide levels in surrounding tissues.

Answer 364

A

Heat generated by active tissues causes vasodilation.

Answer 365

A

nitric oxide, prostaglanidins, and more

Answer 366

A

Histamine

Answer 367

A

sympathetic

Answer 368

A

It binds to alpha-adrenergic receptors on smooth muscle.

Answer 369

A

NE and E from adrenal medulla become endocrine hormones and bind alpha-adrenergic receptors on smooth muscle.

Answer 370

A

vasodilation

Answer 371

A

beta2-adrenergic receptors

Answer 372

A

In heart and skeletal muscle arteriole smooth muscle cells.

Answer 373

A

reduces, increase, increased

Answer 374

A

They function to increase diffusion between blood and tissues.

Answer 375

A

surface area, blood pressure

Answer 376

A

A single layer of simple squamous epithelial cells.

Answer 377

A

Down concentration gradients

Answer 378

A

Through pores between epithelial cells

Answer 379

A

Large plasma proteins that cannot leave capillary.

Answer 380

A

Through the endothelial cells

Answer 381

A

Edema or fluid accumulation in the interstitial space and tissues

Answer 382

A

Movement of water and small molecules into interstitial space around cells

Answer 383

A

Movement of water back into the capillary.

Answer 384

A

It serves as a low pressure blood reservoir and returns blood to the heart/

Answer 385

A

little, large

Answer 386

A

Driving pressure of the cardiac cycle, sympathetic activity, one-way venous valves, skeletal muscle pump and respiratory pumps, and cardiac suction during diastole.

Answer 387

A

Total peripheral vascular resistance (TPR) and cardiac output (CO)

Answer 388

A

Mechanoreceptors and chemoreceptors

Answer 389

A

A type of mechanoreceptor on the carotid arteries and aorta that sense chances in MAP and signal to the cardiovascular control center in the medulla (baroreflex activation)

Answer 390

A

Peripheral chemoreceptors

Answer 391

A

increase, decrease

Answer 392

A

HR, SV, and TPR

Answer 393

A

Low pressure baroreceptors

Answer 394

A

Activate sympathetic neurons extending to the kidneys. Reduces sodium and water loss by reducing kidney blood filtration. Activated the Renin-Angiotensin-Aldosterone system. Increases animal water retention, blood volume, and MAP over time.

Answer 395

A

Atrial natriuretic peptides (ANPs)

Answer 396

A

Travel through blood and increase kidney excretion of sodium and water in urine. They also inhibit the Renin-Angiotensin-Aldosterone system.

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