1-Cell Adaptation, cell injury/cell death

Question 1

Four major patterns of cellular adaptation

Answer 1

• hypertrophy
• hyperplasia
• atrophy
• metaplasia

Question 2

Hypertrophy

Answer 2

• increase in SIZE of cell, =increased organ size
• increase in size is due to increased production of CELLULAR PROTEINS
• may be physiologic or pathologic

Question 3

example of physiologic hypertrophy

Answer 3

uterus in pregnancy

-heart is another common organ that hypertrophies (myocardial hypertrophy)

Question 4

mechanisms of myocardial hypertrophy

Answer 4

-mechanical stretch (increased work load)
-agonistst (alpha adrenegic hormones, angiotensin)
-growth factors (IGF-1)
All these lead to signal transduction pathways

Question 5

Hyperplasia

Answer 5

• Increase in NUMBER of cells, which usually increases mass
• may occur with hypertrophy
• may be physiologic or pathologic

Question 6

Types of physiologic hyperplasia

Answer 6

• Hormonal (puberty)

- compensatory (regrowth of liver)

Question 7

Pathologic hyperplasia

Answer 7

• hormonal/growth factors

- eg endometrial or prostatic hyperplasia

Question 8

mechanisms of hyperplasia

Answer 8

• proliferation of mature cells driven by growth factors

- increased production of new cells from stem cells

Question 9

Atrophy

Answer 9

• decreased cell size and number, =reduced size of tissue or organ
• may be physiologic or pathologic
• fundamental change is a decrease in cell size and organelles; reduction in metabolic needs may permit survival

Question 10

common causes of pathologic atrophy

Answer 10

• decreased workload (disuse atrophy, like with an arm in a cast)
• loss of innervation (denervation atrophy)
• diminished blood supply
• inadequate nutrition
• loss of endocrine stimulation
• pressure (like bed sores)

Question 11

mechanisms of atrophy

Answer 11

• decreased protein synthesis due to reduced metabolic activity
• increased protein degradation in cells due to activation of UBIQUITIN LIGASES
• increased autophagy

Question 12

autophagy

Answer 12

engulfment and degradation of cell’s own components

Question 13

Metaplasia

Answer 13

• replacement of one differentiated cell type by another
• often represents an adaptation to stress by substituting cells better able to withstand stress
• either epithelial or mesenchymal cells may undergo metaplasia
• REVERSIBLE

Question 14

common area of metaplasia

Answer 14

lungs, caused by irritation, especially from smoking.

- the cells go from ciliated columnar to squamous cells (squamous metaplasia)

Question 15

potential downside of metaplasia

Answer 15

• loss of certain cell functions (like the ciliary activity in the lungs)
• ?? predisposition to development of neoplasia (process of new growth, controversial)

Question 16

mechanisms of metaplasia

Answer 16

• re-programming of stem cells to differentiate along a new pathway
• NOT a change in an already differentiated cell
• differentiation is effected by cytokines, growth factors and extracellular matrix components that promote gene expression

Question 17

Types of cellular adaptations:

Answer 17

1. Hypertrophy-increase in size of cells
2. Hyperplasia-increase in number of cells
3. Atrophy-decrease in cell size, number
   4 Metaplasia-replacement of one differentiated cell type by another

Question 18

chronic irritation leads to what type of cellular adaptation?

Answer 18

Metaplasia

Question 19

in there is a decrease in nutrients or stimulation, what will the adaptation be?

Answer 19

Atrophy

Question 20

If there is a stimulus that is Physiologic/pathologic (growth factors, hormones, increased demand) the adaptation will be?

Answer 20

Hypertrophy or hyperplasia; or both

Question 21

intracellular accumulations

Answer 21

• substances may be normal cellular constituents (lipids, carbohydrates, proteins) or abnormal substances (exogenous or endogenous)
• may be transient or permanent
• may be harmless or toxic

Question 22

steatosis

Answer 22

fatty change of the liver

-enlarged and yellow

Question 23

anthracosis

Answer 23

carbon pigment deposition in lung

Question 24

Hemochromatosis

Answer 24

Iron overload, can occur in liver or pancreas

Question 25

Pathologic calcification of tissues

Answer 25

• abnormal deposition of calcium salts (usually with smaller amounts of other mineral salts
• Two forms:
  
  • Dystrophic calcification
  • Metastatic calcification

Question 26

Most common type of tissue calcification

Answer 26

Dystrophic calcification

Question 27

dystrophic calcification

Answer 27

• typically found in areas of tissue necrosis

- initiated by cell membrane damage

Question 28

Steps of dystrophic calcification

Answer 28

• Calcium ion binds to phospholipids
• phosphatases generate phosphate groups
• repeated cycles of calcium-phosphate binding
• structural changes result in microcrystal
• propagation with more calcium deposition

Question 29

Metastatic Calcification

Answer 29

• occurs in normal tissues in setting of hypercalcemia

- deposition can occur widely throughout the body

Question 30

The causes of Metastatic calcification

Answer 30

1. Increased secretion of PTH
2. destruction of bone
3. vitamin D-related disorders
4. renal failure

Question 31

Causes of cell injury

Answer 31

• Oxygen deprivation (hypoxia and ischemia)
• physical, chemical, and infectious agents
• genetic derangements, immunologic reactions
• nutritional imbalances

Question 32

Hypoxia

Answer 32

• oxygen deficiency

- interferes with AEROBIC oxidative respiration

Question 33

ischemia

Answer 33

• loss of blood supply, or mismatch of blood supply and tissue demand due to
  
  • impeded arterial flow or
  • reduced venous drainage
• the MOST COMMON cause of tissue hypoxia

Question 34

Examples of generalized hypoxia

Answer 34

• pneumonia
• CNS depression
• high altitude
• anemia of blood loss
• CO poisoning

Question 35

examples of Ischemia

Answer 35

• Atherosclerosis
• thromboembolism (blood clot that gets dislodged)
• external compression of artery by tumor
• severe hypotension (poor blood flow)

Question 36

Which injures tissues faster, hypoxia or ischemia?

Answer 36

Ischemia

Question 37

infarction

Answer 37

irreversible injury/cell death

Question 38

What ceases during ischemia?

Answer 38

Delivery of both oxygenated blood and substrates for glycolysis

Question 39

Mechanisms of cell injury

Answer 39

• depletion of ATP (eg ischemia)
• damage to mitochondria
• influx of clacium
• accumulation of oxygen-derived free radicals (oxidative stress)
• defects in membrane permeability
• damage to DNA and proteins

Question 40

reversible injury

Answer 40

Changes related to reduced oxidative phosphorylation with depleted ATP
-swelling of ER and mitochondria; membrane blebs; clumping of nuclear chromatin

Question 41

two main morphologic correlates of reversible injury:

Answer 41

• Cellular swelling due to failure of ion pumps, water influx (hydropic change, vacuolar degeneration)
• fatty change, (usually live and myocardium)

Question 42

Is necrosis physiologic, pathologic, or both?

Answer 42

ALWAYS PATHOLOGIC

Question 43

Is apotosis physiologic, pathologic, or both?

Answer 43

-frequently physiologic, but may be pathologic

necrosis and apoptosis may occur in response to the same injury

Question 44

Necrosis: cytoplasmic changes

Answer 44

• sever damage to cell membrane with loss of integrity
• leakage of contents
• digestion of cell by enzymes from cell’s lysosomes or leukocytes
• phospholipids phagocytosed or degraded to fatty acids; calcification results in calcium soaps; sometimes necrotic cells/tissue become calcified

Question 45

necrosis: three patterns of nuclear changes

Answer 45

• due to breakdown of DNA and chromatin
  1. Karyolysis
  2. pyknosis
  3. Karyorrhexis

Question 46

Karyolysis

Answer 46

fading of nucleus due to deoxyribonuclease activity

Question 47

Pyknosis

Answer 47

nuclear shrinkage and increased basophilia due to DNA condensation

Question 48

Karyorrhexis

Answer 48

fragmentation and eventual disappearance of pyknotic nucleus

Question 49

Types of tissue necrosis

Answer 49

• coagulative
• liquefactive
• caseous
• fat
• fibrinoid
• (gangrene)

Question 50

coagulative necrosis

Answer 50

“cells are mummified”

• basic tissue architecture is preserved
• injury denatured not only structural proteins but also enzymes; proteolysis is blocked
• eventually necrotic cells are phagocytosed/digested by leukocytes
• typical of ischemic infarcts (except in brain)

Question 51

Liquefactive necrosis

Answer 51

• usually in setting of microbial infections
• inflammatory cells release enzymes that digest (liquefy) fissue
• associated with the formation of PUSS
• typical of cerebral infarcts
• “Wet gangrene”

Question 52

Gangrene

Answer 52

• usually refers to ischemic necrosis (typically of a limb)
• coagulative necrosis (dry gangrene)
• if complicated by bacterial infection, also undergoes liquefactive necrosis (wet gangrene)

Question 53

Caseous necrosis

Answer 53

• most often associated with tuberculous infection
• cheese-like appearance
• cells fragmented, lysed; tissue architecture not identifiable
• usually surrounded by granuloma (special form of inflammatory response)

Question 54

Fat necrosis

Answer 54

• focal areas of fat destruction
• associated with acute pancreatitis, with release of lipases into pancreas and peritoneal cavity;
• adipocyte membranes liquefied; release fatty acids which combine with calcium=fat saponification

Question 55

fibrinoid necrosis

Answer 55

• usually seen in immune reactions involving blood vessels
• deposition of antigen-antibody complexes in vessel wall
• fibrin leaks out of vessel
• BRIGHT PINK amorphous appearance

Question 56

apoptosis

Answer 56

• cell membrane integrity is largely maintained
• active, energy-dependent process; not associated with ATP depletion
• characterized by nuclear dissolution, fragmentation of the cell, followed by removal of cell debris
• irreparable damage to DNA or proteins, or with deprivation of growth factors

Question 57

causes of apoptosis

Answer 57

• programmed cell destruction in embryogenesis
• involution of hormone-dependent tissues
• cell loss in proliferating cell populations
• senescent cell loss
• elimination of self-reactive lymphocytes
• cell death induced by cytotoxic T lymphocytes
• DNA damage (ie radiation)
• accumulation of misfolded proteins
• some infections
• pathologic atrophy after duct obstruction

Question 58

Necrosis summary

Answer 58

• always pathological
• ATP depletion
• membrane injury
• many cells
• cell swelling; disrupted organelles
• inflammation

Question 59

Apoptosis summary

Answer 59

• pathological or physiological
• gene activation; proteolytic enzymes
• single cells
• intact organelles; apoptotic bodies
• no inflammation; phagocytosis or apototic bodies