BL

Question 1

How do cells attach to the BM?

Answer 1

Hemidesmosomes OR focal adhesions (intracellular actin filaments connected to integrins which connect to the ECM)

Question 2

2 main functions of integrins

Answer 2

Attach the cell cytoskeleton to the ECM, signal transduction from the ECM to the cell

Question 3

Give examples of static, stable, and labile cells

Answer 3

Static/permanent: don’t regenerate, CNS, cardiac and skeletal myocytes
Stable: regenerate when necessary e.g. fibroblasts, endothelium, SM cells
Labile: constantly multiply with short lifespan e.g. blood, epithelium

Question 4

Differences between prokaryote and eukaryote

Answer 4

Pro: no nucleus, no mitochondria, cell wall

Question 5

Where are stereovilli found?

Answer 5

Middle ear hair cells and epididymis

Question 6

Where are cilia found?

Answer 6

Fallopian tube, bronchioles

Question 7

Name three fibres in CT and their functions

Answer 7

Collagen (high tensile strength and flexible), reticular (supporting framework), elastin (allows recoil)

Question 8

What is ground substance

Answer 8

Viscous, high water content, contains proteoglycans (which are core protein + GAGs)

Question 9

Name a glycosaminoglycan and what it does

Answer 9

Hyaluronic acid- attracts water, bound to proteoglycans, in the ground substance of cartilage, because of its swelling it resists compression

Question 10

What is a proteoglycan

Answer 10

core protein + GAGs attached

Question 11

Describe structure of types of CT proper (general CT)

Answer 11

Loose: sparse collagen, many cells, lots of ground substance, viscous
Dense: lots of collagen, few cells, not much ground substance

Question 12

What is the main role of loose CT and therefore where is it found

Answer 12

Good at transport/diffusion because lots of ground substance and viscous, so located beneath epithelium or around small blood vessels

Question 13

Describe the structure of types of dense CT

Answer 13

Regular has collagen in parallel bundles with fibroblasts in between to withstand stress in a single direction ie. tendons, ligaments, aponeuroses. Irregular has collagen in multiple directions with fibroblasts between for stress in multiple directions e.g. submucosa of intestine, deep layers of dermis.

Question 14

What is the structure of collagen in ligaments?

Answer 14

Densely packed in parallel bundles but undulate (like super noodles) and arranged in fascicles separated by loose CT

Question 15

What is an aponeurosis? and name one

Answer 15

Flat sheet of dense regular CT with bundles of fibres in one layer arranged 90 degrees to adjacent layers e.g. linea alba

Question 16

Name the layers of the abdominal wall in order

Answer 16

Skin, SC fat, external oblique, internal oblique, rectus abdominus, transversus abdominus

Question 17

What type of CT is the dermis?

Answer 17

Dense irregular (resists multiple stress directions)

Question 18

What do fibroblasts do?

Answer 18

Synthesis ground substance, procollagen, GAGs, glycoproteins
Important in wound healing and scar formation
Myofibroblasts contain actin and do wound contraction

Question 19

What types of collagen are there and where are they found

Answer 19

I- fibrils aggregate into fibres: skin, tendon, bone
II-fibrils do not form fibres (hyaline and elastic cartilage) cartilage
III-Fibrils form fibres around structures (reticulin)blood vs, LN capsule
IV- BM

Question 20

What is the structure of type I collagen?

Answer 20

Triple helix of a chains

Question 21

What do you need vitamin C for?

Answer 21

The intracellular production of procollagen by fibroblasts

Question 22

What is Marfan’s syndrome?

Answer 22

AD problem with fibrillin so elastic tissue is abnormal (abnormally tall, frequent joint dislocation, arachnodactyly, risk of aortic rupture)

Question 23

Where is elastin found?

Answer 23

Tunica media of aorta (produced by SM cells) and lungs

Question 24

Difference between white and brown adipose cells?

Answer 24

White contain one lipid droplet with nucleus pushed to the side, role in fuel reserve, thermal insulation, shock absorption.
Brown contain many lipid droplets and a central nucleus, especially found in newborn close to scapula, sternum, axillae, also present in upper chest and neck of adults, in thermogenesis

Question 25

Why are brown fat cells brown?

Answer 25

Rich vascular supply and abundant mitochondria

Question 26

Tell me about ghrelin and letpin

Answer 26

Ghrelin released from stomach and signals hunger, leptin released from adipose cells to tell you to stop eating

Question 27

Explain the difference between CT, collagen, and cartilage

Answer 27

CT is loose or dense and a major group of body tissue types
Collagen is one fibre of CT (the others are reticular and elastin)
Cartilage is a type of CT that has type II collagen

Question 28

Name components of the lymphatic system

Answer 28

MALT, GALT, tonsils. Peyer’s patches (ileum), LNs, thymus, spleen

Question 29

How does lymph move?

Answer 29

Deep lymphatics moved by adjacent muscles, abdo/thorax large lymphatics have SM in their walls

Question 30

Where are follicular DCs?

Answer 30

In germinal centres, can cause B cell prolif

Question 31

Functions of spleen

Answer 31

Destroys RBCs, antigen presentation, B and T cell activation, macrophages remove antigen from blood

Question 32

What happens following splenectomy?

Answer 32

BM and liver can take over destroying RBCs, but increased risk of encapsulated (meningococcus) and malaria infection, increased risk of DVT and PE (maybe due to increased platelets?)

Question 33

When can the spleen enlarge?

Answer 33

In response to systemic infection e.g. glandular fever, malaria, septicemia

Question 34

When the thymus involute?

Answer 34

After puberty, by late teens is mostly fat

Question 35

Where do neutrophils, mast cells, monocytes and basophils come from?

Answer 35

Myeloblast, which comes from a common myeloid progenitor

Question 36

Where is McBurney’s point?

Answer 36

Between umbilicus and ASIS, 2/3 from umbilicus

Question 37

What occurs at the sternal angle?

Answer 37

T4/5 level, 2nd rib, aortic arch, tracheal bifurcation

Question 38

What occurs at the level of the umbilicus

Answer 38

L3/4, bifurcation of aorta

Question 39

Top of iliac crest is which level?

Answer 39

L4

Question 40

Where is BM harvested from?

Answer 40

Iliac crest

Question 41

Name layers of the gut mucosa

Answer 41

Epithelium, lamina propria, muscularis mucosae

Question 42

What are serous membranes?

Answer 42

2 part membranes that line body cavities that don’t open to exterior- peritoneum, pleural sacs, pericardial sac. Has epithelial layer and thin CT layer

Question 43

What is mesothelium?

Answer 43

Simple squamous epithelium lining the pleural sac, pericardium and peritoneum

Question 44

Name locations of simple squamous epithelium

Answer 44

Blood vessels (endothelium), pericardium/pleural sac/peritoneum (mesothelium), loop of henle, Bowman’s capsule, pulmonary alveoli

Question 45

Functions of simple squamous epithelium

Answer 45

Barrier (Bowman’s capulse), lubrication (mesothelium), gas exchange (alveoli)

Question 46

Where are simple cuboidal cells found?

Answer 46

Lines pancreatic duct, surround thyroid glands and synthesise thyroxine, CDs of kidney, surface of ovary

Question 47

Functions of simple cuboidal cells?

Answer 47

Absorption and secretion in exocrine glands and kidney tubules, covering ovary, synthesis of thyroxine

Question 48

Where are simple columnar cells found?

Answer 48

Fallopian tubes, colon

Question 49

Where are simple columnar cells with microvilli found?

Answer 49

Jejunum

Question 50

Function of simple columnar cells?

Answer 50

Absorption, secretion and lubrication in SI&LI, transport in fallopian tubes

Question 51

Where is pseudostratified epithelium found?

Answer 51

URT (with cilia), nasal cavity, parotid gland, epididymis, vas deferens

Question 52

What are functions of pseudostratified epithelium?

Answer 52

Mucus secretion and particle trapping and removal (URT),

Question 53

Where are stratified squamous cells found?

Answer 53

Vagina, skin, oesophagus, oral cavity

Question 54

Name layers of epidermis

Answer 54

Stratum corneum, granular layer, prickle cell layer, basal layer dermis

Question 55

Why is the basal layer important in the epidermis?

Answer 55

Keratinocyte mitosis occurs here, then move upwards to the prickle layer where they terminally differentiate

Question 56

What happens in the granular layer?

Answer 56

Keratinocytes lose their plasma membrane and become corneocytes

Question 57

How long does it take for a keratinocyte to move upwards to the stratum corneum?

Answer 57

28-40 days

Question 58

Name cells of the epidermis

Answer 58

Keratinocytes, corneocytes (in stratum corneum), Langerhans, melanocytes

Question 59

What is transitional epithelium?

Answer 59

Stratified epi that can change shape from cuboidal/columnar to flat

Question 60

Where is transitional epi found?

Answer 60

Ureter, bladder, urethra, renal calyces

Question 61

Name a unicellular gland

Answer 61

Goblet cell!

Question 62

What effects can CF have on GI?

Answer 62

Meconium ileus, constipation, poor absorption

Question 63

What are merocrine, apocrine and holocrine secretion?

Answer 63

Merocrine is exocytosis, apocrine is droplets covered with plasma lemma e.g fat droplets in milk, holocrine is whole cell breakdown e.g. sebaceous gland of skin

Question 64

Name some tubular glands

Answer 64

Intestinal crypts, gastric pits

Question 65

What effects can CF have on pancreas?

Answer 65

Exocrine secretions are dehydrated, become thick and block the ducts, pancreatitis and fibrosis, poor absorption due to blocking enzymes

Question 66

<5mm lump =

Answer 66

papule

Question 67

5-10mm lump=

Answer 67

nodule

Question 68

small water blister =

Answer 68

vesicle

Question 69

larger water blister -

Answer 69

bulla

Question 70

pus filled vesicle =

Answer 70

pustule

Question 71

thread vein =

Answer 71

telangiectasia

Question 72

non palpable area of discoloration =

Answer 72

macule

Question 73

macule >2cm =

Answer 73

patch

Question 74

palpable, flat topped area >2cm =

Answer 74

plaque

Question 75

loss of epidermis

Answer 75

erosion

Question 76

loss of epi and dermis

Answer 76

ulcer

Question 77

What pathology is involved in psoriasis?

Answer 77

Rapidly proliferation in basal layer, desquamation of stratum corneum, leukocytes infiltrate

Question 78

Thickening of the skin =

Answer 78

lichenification

Question 79

Name the 3 types of cartilage

Answer 79

Hyaline, elastic, fibrocartilage

Question 80

What is the only cell type found in healthy hyaline cartilage?

Answer 80

Chondrocytes

Question 81

What cell type produces ECM in the cartilage?

Answer 81

Chondrocytes

Question 82

Difference between collagen and cartilage?

Answer 82

Collagen is a type of fibre found in CT. Cartilage is a type of CT. Type II collagen is found in hyaline cartilage.

Question 83

How do GAGs attract water?

Answer 83

They have lots of negative charges

Question 84

Describe the structure of the three types of cartilage

Answer 84

Hyaline- type II collagen, GAGs, hyaluronic acid
Elastic- hyaline + elastin fibres
Fibrocartilage- hyaline + type I collagen

Question 85

If chrondrocytes are recently divided, what are they called?

Answer 85

Isogenous groups

Question 86

Role of hyaline cartilage in bones?

Answer 86

Precursor of bones for fetuses that develop by endochondrial ossification, some remains on long bones at the articulating surface and epiphyseal plate

Question 87

What covers hyaline cartilage and what is its function?

Answer 87

Perichondrium which has cells that develop into chondroyctes

Question 88

Explain appositional and interstitial growth

Answer 88

Appositional is chrondoblasts from the perichondrium secreting matrix
Interstitial is from chondrocytes dividing and producing isogenous groups that deposit matrix

Question 89

Each chondrocyte lies in a…

Answer 89

Lacuna

Question 90

What is NOT located at articulating surfaces and epiphyseal growth plates?

Answer 90

Perichondrium

Question 91

Name regions of a bone

Answer 91

Epiphysis, metaphysis, diaphysis

Question 92

What type of collagen is found in fibrocartilage?

Answer 92

Type I

Question 93

What type of collagen is found in hyaline cartilage?

Answer 93

Type II

Question 94

Where is elastic cartilage

Answer 94

Pinna, EAM, epiglottis, eustachian tube

Question 95

What cell types are in fibrocartilage?

Answer 95

Chondrocytes and fibroblasts

Question 96

Which types of cartilage have perichondrium?

Answer 96

Hyaline and elastic, NOT fibrocartilage

Question 97

Where is fibrocartilage found?

Answer 97

IV discs, menisci of knee, pubic symphysis

Question 98

Where is hyaline cartilage found?

Answer 98

Rib, nose, trachea, bronchi

Question 99

How do long bones grow?

Answer 99

Hyaline is template for endochondral ossification which increases its length. Periosteal ossification increases the girth of the bone which is intramembraneous ossification. Cartilage is replaced by bone.

Question 100

Describe the zones of epiphyseal growth

Answer 100

Cartilage to bone:

1. Zone of reserve cartilage (not actively becoming bone)
2. Zone of proliferation: chondrocytes multiply and arrange in columns
3. Zone of hypertrophy: chondrocytes stop dividing and just grow, walls of lacunae become thin.
4. Zone of calcification: between columns of the chondrocytes matrix is deposited and calcifies.
5. Zone of resorption: chondrocytes die as the lacuna walls breakdown, leaving columns between the calcified matrix that are invaded by blood vessels and osteoblasts/clasts. Clasts remove the temporary matrix laid down earlier and blasts deposit matrix in the bony spicule (become osteocytes if surrounded by matrix)

Question 101

What happens in the zone of resorption?

Answer 101

chondrocytes die as the lacuna walls breakdown, leaving columns between the calcified matrix that are invaded by blood vessels and osteoblasts/clasts. Clasts remove the temporary matrix laid down earlier and blasts deposit matrix in the bony spicule (become osteocytes if surrounded by matrix)

Question 102

What type of cartilage covers synovial joints?

Answer 102

Hyaline or fibrocartilage

Question 103

How do flat bones and long bones develop?

Answer 103

Long bones by endochondral ossification and flat bones by intramembranous ossification

Question 104

What is intramembranous ossification?

Answer 104

Flat bones develop like this and develop from mesenchymal tissue. Does not replace an existing template. e.g. skull, clavicle, scapula. Also thickens long bones at their periosteal surfaces (appositional growth)

Question 105

What are the stages of intramembranous ossification

Answer 105

Mesenchymal stem cells (MSCs) form a nidus (a tight cluster). MSCs become osteoprogenitor cells (more Golgi and ER), become osteoblasts and lay down ECM containing type I collagen (osteoid). Osteoid mineralises to form spicules containing osteocytes surrounded by osteoblasts. Spicules join to form trabeculae, which merge to form woven bone, then replaced by mature compact bone

Question 106

Spicule + spicule =

Answer 106

Trabeculae

Question 107

What are the two types of bone?

Answer 107

Spongy/cancellous (spaces filled with BM) and compact bone on external surfaces of bone

Question 108

What are Haversian and Volkmann’s canals?

Answer 108

Haversian travels up an osteon (so at the centre of a ring), Volkmann’s travels across an osteon
Carry blood vs, lymphatics and nerves

Question 109

How is mature bone arranged?

Answer 109

Concentric lamellae of osteons

Question 110

What are canaliculi (in bone)

Answer 110

Tiny canals which osteocytes project their cytoplasmic processes into to exchange nutrients between themselves

Question 111

What structural differences are there between spongy and compact bone?

Answer 111

Compact bone has Haversian and Volkmann’s canals, spongy doesn’t. Spongy has BM in its gaps

Question 112

What is a cutting cone?

Answer 112

Involved in bone remodelling, bores a tunnel through bone with osteoclasts, followed later by osteoblasts to lay down osteoid

Question 113

Describe key components of bone

Answer 113

65% calcium hydroxypatite crystals, 23% type I collagen

Question 114

Describe stages of fracture repair

Answer 114

1. Haematoma (blood vessels and periosteum break) and granulation tissue forms. Phagocytes and osteoclasts remove dead tissue, macrophages remove clot
2. Soft callus forms which is fibrocartilaginous tissue to splint the fracture, bony trabeculae develop as osteoblasts invade site. New blood vessels infiltrate
3. Hard callus of spongy bone forms from endochondral and intramembranous ossification (from 2 days-2months)
4. Spongy bone replaced by compact bone and bone remodelling occurs

Question 115

Define osteoporosis

Answer 115

Enhanced bone resorption:formation, depletion of bone mass. Spongy bone is regularly remodelled but in osteoporosis the osteoclast resorption bays are not filled in again

Question 116

What is primary osteoporosis?

Answer 116

Either type 1 or 2:
Type 1 in postmenopausal due to increased osteoclasts from decreased oestrogen
Type 2 is senile osteoporosis, >70yo due to reduced osteoblast function x

Question 117

Risk factors for osteoporosis

Answer 117

Genetic (black bone mass higher than white or asian)
Insufficient calcium intake, insufficient calcium absorption via reduced vit D/decreased renal activation of vit D, immobilisation of bone, smoking

Question 118

What colour skeletal muscle fibres exist and what’s the difference

Answer 118

Red: small, very vascularised, slow weak contraction, fatigues slowly
Intermediate
White: large, poor vascularisation, few mitochondria, fast, strong contraction, fatigues quickly (e.g. finger muscles)

Question 119

Where is myoglobin present?

Answer 119

Skeletal and cardiac muscle, NOT smooth

Question 120

How does Hb relate to myoglobin?

Answer 120

Hb gives up oxygen to myoglobin, especially if low pH (as in active muscles from CO2/lactic acidosis)

Question 121

What are epimysium, perimysium, and endomysium

Answer 121

Epimysium around a muscle, perimysium around a fascicle, endomysium around a muscle fibre

Question 122

Describe the organisation of a sarcomere

Answer 122

Z discs at each end and H zone in the middle. Thick A band in the middle, think I bands either side

Question 123

How often do muscles get remodelled?

Answer 123

Continually! Replaced in 2 weeks

Question 124

Causes of atrophy

Answer 124

Disuse, with age (>30yo), denervation (LMN lesions)

Question 125

How do muscles get longer?

Answer 125

Sarcomere addition

Question 126

What’s in a skeletal muscle?

Answer 126

Fasicles –> muscle fibre –> myofibrils –> myofilaments

Question 127

What is the thin filament?

Answer 127

Actin with tropomyosin coiled around, and troponin complex attached to tropomyosin

Question 128

Where is creatine kinase released from?

Answer 128

Skeletal muscle, brain, heart (can indicated IM injection, vigorous exercise, fall, rhabdomylolysis, muscular dystrophy, AKI

Question 129

Describe myosin structure

Answer 129

Thick rod with two protruding heads. In the centre of the sarcomere it has no heads.

Question 130

How does calcium cause muscle contraction?

Answer 130

Calcium binds to TnC of troponin, which causes a conformational change in tropomyosin and it moves away from blocking the actin binding site so that myosin head can bind actin

Question 131

How does myosin head detach from actin?

Answer 131

As ATP attaches myosin detaches . Thats why in rigor mortis the myosin is still attached to actin.

Question 132

What causes cocking of the myosin head?

Answer 132

Hydrolysis of ATP to ADP and Pi

Question 133

Describe the process leading to contraction of skeletal muscle (start with nerve impulse)

Answer 133

Nerve impulse arrives at NMJ, Ach released into synaptic cleft, causes end plate potential of sarcolemma, voltage Na channels open, Na enters cell, depolarisation spread to T tubules, voltage sensors in T tubules trigger opening of Ca channels from terminal cisternae (of SR) into sarcoplasm, Ca binds to TnC

Question 134

What’s special about cardiac muscle?

Answer 134

Central nuclei, striated, intercalated disc, branching

Question 135

What are intercalated discs for in cardiac muscle?

Answer 135

Have gap junctions for electrical coupling

Question 136

What are ANP (from atria) and BNP (from ventricles) raised in?

Answer 136

HF

Question 137

What are the actions of ANP/BNP?

Answer 137

Increase GFR for natriuresis and diuresis, vasodilation to reduce BP (counteract RAAS)

Question 138

Describe structure of Purkinje fibres

Answer 138

Have glycogen +++, gap junctions +++, sparse myofilaments, rapid conduction

Question 139

Describe structure of SM cells

Answer 139

Fusiform (spindle), no T tubules, no sarcomeres (but contraction still actin-myosin), slower contraction more sustained, less ATP needed. Actin and myosin arranged diagonally spiralling across so that it contracts in a twisting way!

Question 140

Name two modified SM cells

Answer 140

Myoepithelial that surround exocrine glands (sweat, saliva, mammary) and in ciliary muscle
Myofibroblasts at wound healing to contract wound and tooth eruption

Question 141

Which muscle cells can regenerate?

Answer 141

SM can (e.g. pregnant uterus)
Skeletal muscle cells can't but satellite cells (their progenitors) can. Satellite cells can also fuse with muscle cells to increase mass.
Cardiac muscle can't- fibroblasts divide and lay down scar tissue

Question 142

Name end arteries and an absolute end artery

Answer 142

Coronary, splenic, cerebral, renal. Absolute end artery is central artery to the retina

Question 143

Tunica media and tunica adventitia have which types of muscle fibres?

Answer 143

Media has circular muscle layers, adventitia has longitudinal

Question 144

What is an arteriole?

Answer 144

Arteries with a diameter of <0.1mm, with 1-3 layers of muscle in tunica media only (arteries have x30)

Question 145

What are arteries that supply blood to capillary beds called?

Answer 145

Metarterioles

Question 146

What controls flow to capillary beds?

Answer 146

Precapillary sphincters of metarterioles

Question 147

What vessels do capillaries lead to?

Answer 147

Post capillary venules

Question 148

What are the only two cell types of a capillary and what do they do?

Answer 148

Single layer of endothelial + pericytes. Pericytes can divide into SM cells or fibroblasts in angiogenesis/healing

Question 149

Veins vs arteries

Answer 149

Veins are larger diameter, higher capacitance, thinner wall with more CT and less elastic and muscle

Question 150

Name the 4 layers of gut wall

Answer 150

Mucosa (epithelium, lamina propria, muscularis mucosae), submucosa, muscularis externae, serosa

Question 151

Which layer are Peyer’s patches often found?

Answer 151

Lamina propria of mucosa

Question 152

Which layer of gut are glands, A&Vs, nerves found in?

Answer 152

Submucosa

Question 153

What muscle types are found in muscularis externa?

Answer 153

Inner circular and outer longitudinal

Question 154

What epithelium makes up the gut serosa

Answer 154

Simple squamous (mesothelium)

Question 155

Name contents/function of saliva

Answer 155

IgA, amylase, lipase, lubricates food, high calcium for teeth,

Question 156

Name the two innervation locations in the gut layers

Answer 156

Meissner’s plexus in the submucosa, Auerbach’s plexus between the two layers of the muscularis externa

Question 157

Gastric glands are what types of glands?

Answer 157

Tubular

Question 158

Gut glands are in the _____ layer, but gastric glands are in the ____

Answer 158

Submucosa, mucosa

Question 159

What can damage mucous cells and what is their function?

Answer 159

Aspirin and alcohol can damage mucous cells. Mucus contains HCO3 to neutralise and is resistant to pepsin

Question 160

Describe a gastric gland

Answer 160

Pit at top with mucous cells, then isthmus with stem cells and parietal cells, then neck, the base with chief cells, and G cells

Question 161

What glands are in the duodenum?

Answer 161

Brunner’s glands, which secrete HCO3

Question 162

Give example of paracrine control in gut

Answer 162

Histamine controls acid production

Question 163

What is the hepatic portal system?

Answer 163

Two capillary beds in series- one in stomach/gut and one in liver sinusoids

Question 164

What converts ammonia (toxic and can cross BBB) to urea

Answer 164

Liver

Question 165

What are lacteals and where do they lead?

Answer 165

Lymphatic vessels that drain into other lymphatics –> thoracic duct –> enters circulation between left jugular vein/left subclavian –> lipids enter liver through hepatic artery

Question 166

What doesn’t travel in the portal vein?

Answer 166

Lipids and ADEK vits

Question 167

What does the liver produce?

Answer 167

Albumin, glycogen, IGF-1, thrombopoetin, angiotensinogen, activates vit D, bile

Question 168

What blood vessels are connected to the liver

Answer 168

Hepatic artery (from coeliac trunk) and hepatic portal vein lead in, and hepatic vein leading to IVC drains

Question 169

What’s a sinusoid (in liver)

Answer 169

Mixing of arterial and venous blood from hepatic artery and hepatic portal vein

Question 170

What’s the space of disse?

Answer 170

Gaps between sinusoids and hepatocytes (dissed by the sinusoids and by the hepatocytes)

Question 171

Where are Kupffer cells?

Answer 171

Lining the sinusoids

Question 172

What are stellate/Ito cells

Answer 172

Store vit A in the liver, found in space of disse

Question 173

Three signs of Horner’s syndrome

Answer 173

Miosis, ptosis, and anhidrosis

Question 174

How can lung cancer cause a hoarse voice?

Answer 174

Impingement on the left recurrent laryngeal nerve, supplies larynx muscles
OR if aortic aneurysm presses on LRLN

Question 175

What are the conducting and respiratory airways?

Answer 175

Conducting is nasal cavity-terminal bronchioles, respiratory is respiratory bronchioles to alveoli

Question 176

Name the sections air travels through to the lungs

Answer 176

Nasal cavity, pharynx, larynx, trachea, primary bronchi, secondary bronchi, bronchioles, terminal bronchioles, respiratory bronchioles, alveolar ducts, alveoli

Question 177

Name epithelial types in the lungs

Answer 177

Nasal-secondary bronchi is pseudostratified with cilia and goblet cells
Bronchioles-terminal bronchioles is simple columnar with cilia and clara cells
Respiratory bronchioles-alveolar ducts is simple cuboidal with clara cells.
Alveoli is simple squamous

Question 178

Which bronchus is more prone to having things fall down it?

Answer 178

Right bronchus because its more vertical

Question 179

Tell me about cartilage in the lung

Answer 179

Trachea and primary bronchi have C shaped rings, secondary and tertiary bronchi have irregular islands

Question 180

What blood vs supply and drain the lung?

Answer 180

Pulmonary VEIN SUPPLIES and pulmonary ARTERY drains

Question 181

What do clara cells (terminal/respiratory bronchioles) secrete?

Answer 181

Surfactant lipoprotein to stop walls sticking together in expiration

Question 182

What helps keeps the breasts up?

Answer 182

Cooper’s suspensory ligaments

Question 183

What type of glands are mammary?

Answer 183

Modified apocrine (part of cell lost in secretion) sweat glands

Question 184

What is a lobule in the breast?

Answer 184

Many alveoli drained by a single lactiferous duct

Question 185

The hypothalamus produces..

Answer 185

ADH and oxytocin, TRH

Question 186

Give an example of neurocrine secretion

Answer 186

TRH released from hypothalamic neurons travels in blood to anterior pituitary to cause cells to release TSH

Question 187

What are catecholamines, glucocorticoids and mineralocorticoids?

Answer 187

Gluco cortisol, mineral aldosterone, catecholamine adrenaline/NA

Question 188

How is cortisol released?

Answer 188

Hypothalamus released CRH, ant pit releases ACTH, adrenal cortex releases cortisol (zona fasiculata)

Question 189

Describe adrenal gland structure and what each layer makes

Answer 189

Cortex:
Zona glomerulosa- mineralocorticoid aldosterone
Zona fasiculata- glucocorticoid cortisol
Zona reticularis- androgens
Medulla - catecholamines adren/NA

Question 190

What type of cells are in the adrenal medulla?

Answer 190

Chromaffin cells

Question 191

What does the pineal gland produce?

Answer 191

Melatonin

Question 192

Describe spermatogenesis

Answer 192

Diploid spermatogonium divides by mitosis –> 2 diploid primary spermatocytes –> meiosis 1 makes 2 haploid secondary spermatocytes –> meiosis II for 4 haploid spermatids

Question 193

Describe oogenesis

Answer 193

Oogonium is diploid and divides by mitosis for 2 diploid (one primary oocyte and one oogonium), divides by meiosis I to form haploid oocyte and a polar body. Haploid oocyte ovulated and undergoes meiosis II if fertilised to produce haploid ovumx23 chromatids

Question 194

Where does the oocyte pause

Answer 194

Primary oocyte pauses in prophase I of meiosis I

Question 195

Where does fertilisation occur?

Answer 195

Ampulla of fallopian tube

Question 196

How long are sperm and oocytes viable for?

Answer 196

Sperm 5 days, secondary oocyte 12-24hours

Question 197

Difference between gestational age and embryonic age?

Answer 197

Gestational age = embryonic age (time since fertilisation) + 2 weeks

Question 198

What is the germinal stage, embryonic period and fetal period

Answer 198

Germinal stage is fetilisation - 2 weeks, embryonic is 3-8weeks, foetal is 8-term

Question 199

What is hatching?

Answer 199

Blastocyst breaking free of zona pellucida, which is needed to implant

Question 200

What does the trophoblast become?

Answer 200

tropho=food, blast=bud, so food bud! Yolk sac and placenta

Question 201

How is food for the embryo provided before and after 12th week

Answer 201

Pre 12th- histiotrophic (not from maternal blood)

Post 12th- haemotrophic

Question 202

What are normal implantation sites?

Answer 202

Superior and posterior wall (placenta previa if not)

Question 203

What makes up the bilaminar disc

Answer 203

Hypoblast and epiblast (from embryoblast)

Question 204

What happens in the week of 2s?

Answer 204

Trophoblast becomes the cytotrophoblast and syncytiotrophoblast, embryoblast becomes bilaminar (hypoblast and epiblast), hypoblast contributies to 2 cavities (yolk sac and chorionic cavity)

Question 205

What feature appears on the epiblast in 3rd week?

Answer 205

Primitive streak and node. Marks the start of gastrulation

Question 206

What is gastrulation?

Answer 206

Bilaminar disk becomes trilaminar disck (ecto, meso and endoderm). Epiblast cells migrate inwards (forming a pit)

Question 207

How and when do we get left-right asymmetry

Answer 207

Before gastrulation the bilaminar disk is bilaterally symmetrical. After, ciliated cells at the primitive node result in left and right directed signalling molecules (sinus inversus can result from immotile cilia)

Question 208

What is the notochord?

Answer 208

Midline cellular rod located cranially to the primitive streak that develops in week 3. Tells overlying ectoderm to become neuroectoderm and thicken to become the neural tube (neurulation)

Question 209

What are somites?

Answer 209

Paraxial (by the neural tube) mesoderm segments, first pair appear at day 20 until week 5

Question 210

What do somites form?

Answer 210

Dermatome, myotome and sclerotome (bones)

Question 211

What does folding of the embryo do? (week 4)

Answer 211

Pulls amniotic membrane around so embryo is suspended, pulls connecting stalk ventrally, creates a ventral body wall, puts the heart in the right place

Question 212

Name 3 MRI planes

Answer 212

Axial (cutting across transversely, coronal, sagittal