Module 4

Created by

Lilli

Cards (192)

Adaptive changes 
Cells' responses to stress in an attempt to maintain homeostasis
Types of adaptive changes
Hypertrophy: Increase in cell size
Hyperplasia: Increase in cell number
Atrophy: Degeneration of cells
Metaplasia: Change in cell type
Dysplasia: Change in cell abnormally
Reversible injury 
Cells' more extreme response to continued cellular stress causing injury that without proper intervention will lead to severe pathologies that can cause death
Reversible injury 
Generalized cell swelling, plasma blebbing, clumping of nuclear chromatin, decreased ATP generation, loss of cell membrane integrity, defects in protein synthesis, cytoskeleton damage, and DNA damage
Irreversible injury 
Cells' most extreme response to cellular stress over time with no choice but cellular death (apoptosis[controlled]; necrosis[uncontrolled])
Irreversible injury 
Severe ER and mitochondrial swelling, lysosome rupture, blebbing progresses to membrane fragmentation, as well as nuclear membrane rupture and chromatin fragmentation
Factors determining cell response to stress/injury
Labile- continuously replicating cells
Stable- cells capable of division in response to demand (stress)
Permanent- non-dividing cells
Common examples of cellular adaptations 
Connective tissue in the brain from cell death
Increase in organ size due to hyperplasia
Psychological adaptation 
Increase in workload either mechanically or metabolically, or due to hormonal stimulation
Pathological adaptation 
Increase in resistance or abnormal increase in hormonal stimulation, could be caused due to a physical obstruction or may be genetically determined
Possible causes of cell injury
Reactive oxygen and nitrogen species
Neoplasia causing increased hormone production and action
Physical obstruction or decrease in flow of nutrients
Hydropic change 
Acute swelling due to a failure in energy dependent ion pumps within the membrane thus causing a disturbance in ion and fluid homeostasis leading to water overload
Hydropic change 
Macroscopic: enlarged and pale organs (rare to see unless extreme)
Microscopic: cytoplasm will be pale and clear, cloudy swelling
Fatty change 
Increase lipids within the cells leading to hypoxic, or toxic/metabolic injury
Fatty change 
Macroscopic: enlarged and pale organs, soft and greasy
Microscopic: macrovesicular and microvesicular patterns
Glycogen overload 
Buildup of glycogen similar to fatty change
Chromatolysis 
Neurons' internal degeneration of special bodies called nissl bodies within their cell body and dispersed within the cell
Common causes of reversible injury in domestic species 
Reactive oxygen species
Physical agents
Chemicals
Drugs
Toxins
Infectious agents
Immunological dysfunction
Genetic defects
Nutritional deficiencies and imbalance
Progression of reversible to irreversible cell injury
1. Pyknosis
2. Karyorrhexis
3. Karyolysis
4. Absence
Oxidative stress 
Damage caused by free radicals (molecules with an unpaired electron) like ROS or RNS (and your antioxidant lvls are too low to fight of the higher lvls of free radicals)
Hypoxia 
State at which oxygen is not available in sufficient amounts at the tissue level to maintain adequate homeostasis
Ischaemia 
Condition in which blood flow (and thus oxygen) is restricted or reduced within a part of the body
Infarction 
Death of tissue resulting from a failure of blood supply, commonly due to obstruction of a blood vessel by a blood clot or narrowing of the blood-vessel channel
Apoptosis (physiological) 
Programmed cell death that allows the surrounding cells and the organ as a whole to continue to function and maintain homeostasis
Apoptosis (pathological)
Cell death caused by some type of disease
Necrosis is less controlled than apoptosis
Common intracellular/extracellular accumulations
Cytochrome C
Apoptotic proteins
BCL2 receptors
Receptor ligand interactions on the cell surface
Amyloidosis (secondary) 
From chronic inflammation or neoplasia (over production of normal proteins)
Amyloidosis (primary)
From plasma cell tumours
Dystrophic calcification
Calcium build up associated with necrosis (coagulative, caseous, and fat) the dying cells can not regulate their cytoplasmic calcium leading to a build up of calcium in the mitochondria
Metastatic calcification 
Calcium build up occurs in normal cells, secondary to hypercalcemia; large amounts of calcium enter the cell and build up on the organelles, primarily the mitochondria
Gout
Build up of crystals formed from uric acid, primarily an issue in reptiles, birds, and humans since they lack uricase. Commonly caused by a vit A deficiency, high protein diet, and/or renal injury.
Necrosis
Cell size increases, nucleus degrades from pyknosis to karyorrhexis to karyolysis, cell membrane is disrupted and the cell begins digesting itself from destroyed lysozyme enzyme leaking out
Types of necrosis
Coagulative
Liquefactive
Caseous
Gangrenous
Fat necrosis
Coagulative necrosis
Cellular outlines/basic tissues architecture is preserved temporarily; ischemia or toxin induced
Liquefactive necrosis 
Necrosis of cells in the CNS cavity filled with liquefactive necrotic material (pus)
Caseous necrosis
Friable, "cheese like"; component cells dead and architecture lost
Gangrenous necrosis
3 types: Moist, Dry, Gas; necrosis with an infection
Fat necrosis 
Specific necrosis of fat
Absorption 
Spread from the stomach and intestines into the bloodstream as the body takes in and digests the drug