Term
What are the three most common mechanisms by which agents can injure cells? |
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Definition
Impair ATP availability, generation of free radicals, initiating apoptosis |
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Term
What are the three major types of defense mechanisms of cells when they have sublethal injury? |
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Definition
Prevent accumulation of reactive oxygen species(ROS), repair cellular damage, enhanced metabolism or export of toxins/xenobiotics |
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Term
Elaborate on the 3 steps of the cellular damage repair mechanism. |
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Definition
DNA repair enzymes fix altered bases and strand breaks, enzymes metabolize and repair damaged lipids (fatty acid is converted to alcohol and then reesterified), elimination or repair of damaged proteins (degradation in proteosomes, unfolded protein response UPR decreases protein translation increases proteosome/chaperone translation) |
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Term
What are the two processes that a cell can die? |
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Definition
Oncosis/necrosis and apoptosis |
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Term
What causes necrosis of cells versus apoptosis? |
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Definition
Necrosis due to bad Na+ ion pump, ion accumulation, water uptake, swelling and death; coordinated cascade of molecular events leads to programmed cell death |
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Term
True or false: the same agent cannot initiate apoptosis or necrosis. |
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Definition
False, same agent even in different cell types, the type of death depends on type and quantity of initiator |
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Term
Elaborate on the main features of oncosis/necrosis. |
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Definition
Occurs in many adjacent cells, passive response to damage, does not require ATP, disruption of organelles, release of cell contents, strong inflammatory response |
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Term
Elaborate on the main features of apoptosis. |
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Definition
Mainly in single cells, programmed cell death in response to damage, requires ATP, preservation of organelles, little release of contents, little inflammation |
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Term
Name three examples of apoptotic death to physiologic changes. |
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Definition
Thymic atrophy during puberty, post-lactational atrophy of death, post-menopausal atrophy of uterine endothelium |
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Term
List three diseases associated increased apoptosis. |
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Definition
UV light or hypoxia, diabetes, alzheimers |
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Term
List two diseases associated with decreased apoptosis. |
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Definition
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Term
What are the three stages of apoptotic death? |
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Definition
Signaling stage, effector stage, terminal stage. |
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Term
List 4 different apoptotic signals. |
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Definition
Interaction of ligand with receptor (FAS or TNF), DNA damage, Microbial/cytotoxic Tcell products, withdrawal of growth factors or attachment signals |
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Term
In the effector stage of apoptosis, what are the three pathways to caspase activation? |
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Definition
Receptor-mediated assembly of complex to activate, mitochondrial pathway (DNA damage induced), direct caspase actiation from Granzyme B from cytotoxic Tcells |
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Term
What are the 3 methods of cell execution in the terminal apoptotic stage? |
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Definition
Caspase activates endonucleases that fragment DNA, caspases degrade microfilaments, caspases degrade muclear membrane proteins |
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Term
Why is there little inflammation associated with apoptosis? |
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Definition
Cells cleared rapidly, cells don’t release cytokines and proteins that attract cells |
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Term
Define these classic responses to cell injury: hyperplasia, hypertrophy, atrophy, metaplasis. |
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Definition
Increased cell number, increased cell size, decreased cell size, altered function with a change in mature cell type |
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Term
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Definition
Continued cell injury or inflammation cause progressive increases of extracellular matrix deposition. |
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Term
List as many diseases associated with fibrosis as possible. |
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Definition
Cirrhosis, pulmonary fibrosis, chronic myocardial ischemia, atherosclerosis, end stage renal disease, chronic rheumatic valve disease |
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Term
Out of these three cell types, labile, stabile, permanent, identify if they can regenerate if damaged and give examples of cell type. |
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Definition
Yes - epidermis, yes - hepatocytes, no - neurons, cardiac muscle |
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Term
Identify these undesirable comsequences of wound healing: contractures, strictures, adhesions, keloid. |
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Definition
contraction scars limit mobility (burns), circumferential scarring of tubular structure (esophageal scar), fibrous bands bridging serosal surfaces, excessive extracellular matrix causing hypertrophic scar |
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Term
What are the 3 functional phases of tissue repair? |
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Definition
Hemostatic plug formation, inflammatory response, repair and remodeling |
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Term
What occurs during the 3 phases of tissue repair? |
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Definition
Hemostasis, temporary stabilization and barrier, fibrin and thrombin signal monocyte and fibroblast migration; removal of dead tissue and hemostatic plug elements by phagocytes and proteolytic enzymes, macrophages intiate angio/fibrogenesis thru cytokines and GFs; reepithelialization, angiogenesis, fibrogenesis |
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Term
What are the 3 morphologically defined phases of tissue repair? |
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Definition
Hemostatic plug, granulation tissue, scar |
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Term
Is glucose an essential nutrient? |
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Definition
No, it can be generated by the liver from lactate and amino acids |
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Term
How many moles of ATP are created from 1 mole of glucose? |
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Definition
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Term
What drives the inner mitochondrial membrane to create ATP? |
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Definition
The proton electrochemical potential gradient |
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Term
Which transmembrane protein creates the majority of all ATP? |
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Definition
F0F1-ATPase, where the flow of 4 protons creates 1 ATP from ADP |
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Term
How do the substrates for operation of the electron transport chain and ATPase get transported across the mitochondrial membrane: phosphate, ADP, pyruvate? |
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Definition
P/H symporter, ADP/ATP antiporter, uniporter |
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Term
What happens to the process of ATP synthesis in regulation of body temperature? |
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Definition
Brown fat mitochondrial membranes containing UCP (uncoupling) is able to uncouple ATP synthesis and generate heat. |
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Term
How does the uncoupling protein get activated and what does it do? |
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Definition
Activated by cold-induced release of fatty acids and it short circuits the proton gradient in mitochondria reducing ATP generation. |
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Term
How is mitochondria linked to disease? |
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Definition
Mutations in mitochondrial DNA can be linked to rare diseases due to reduced efficiency; e.g. mutated genes coding for respiratory chain complexes |
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Term
The creation of ATP drives what type of gradient that is essential for storage and energy conversion? |
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Definition
Ion gradients; specifically Na/K pumps, generally Na gradients to maintain pH, lower Ca, neurotransmitter accumulation, etc. |
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Term
What is the difference between regulatory volume increase and decrease? |
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Definition
In RVI, the cell is exposed to hypertonic solution so they decrease then actively increase by taking in ions, polyols, and amines; In RVD the cell is in a hypotonic solution, swells, then decreases volume by loss of osmolytes through membrane channels. |
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Term
The rate of PASSIVE water transport depends on what? |
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Definition
Simple osmotic gradient and water permeability of cell. |
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Term
Elaborate on the pump leak hypothesis. |
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Definition
Since the membrane is slightly permeable to Na/K ions the Na/K pump is instrumental in maintaining cell volume. Poisoning of the pump leads to cell volume and death. |
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Term
What is the difference between passive and active water transport? |
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Definition
Passive relies on AQPs and osmotic gradients to move water, whereas Active uses transport of ions into paracellular spaces to drive water into cells against gradient (renal collecting tubes) |
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Term
In regards to oxidative stress on cells, what are the differing effects on the cell at low, moderate, and high exposures? |
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Definition
Transcriptional and translational regulation, initiation of adaptations, sublethal injury or cell death |
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Term
All ROS produce damage to cells: True or False. |
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Definition
False, only excess ROS. H2O2 is cell signal mediator, and some radicals kill bacteria. |
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Term
Which of these diseases is NOT associated with ROS: cancer, aging, reperfusion injury, arthritis, atherosclerosis, hypertension, bronchitis/asthma. |
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Definition
Trick question, all associated. |
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Term
What are the four important ROS, recite in order from least reactive to most reactive to biological molecules? |
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Definition
Superoxide, peroxide, hydroxyl radicals, and reactive nitrogen species. |
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Term
List 3 major factors of superoxide radicals in their reaction to cells. |
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Definition
Major free radical in cell produced by many enzymes, diffuses poorly across membranes, relatively unreactive with DNA, lipid, protein. |
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Term
List 3 characteristics of the ROS peroxide. |
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Definition
Modestly reactive to biological molecules, diffuses well across membranes, made during oxidation in peroxisomes. |
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Term
Elaborate on the ROS effects on DNA, lipids, proteins. |
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Definition
Base mutation, chrome breaks, base changes inducing apoptosis; changes membrane fluidity, become antigenic(antigen producing), produce receptor ligands; modification of SH groups, formation with lysine, cysteine, tyrosine, and protein unfolding. |
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Term
What are some of the progressive effects of ROS on proteins? |
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Definition
Activation of kinases and inhibition of phosphotases activating transcription factors, increasing cell replication, increasing transcription of molecules protecting against ROS, activation of uncoupled protein response/inhibit cell replication, apoptosis. |
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Term
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Definition
is a chemical which is found in an organism but which is not normally produced or expected to be present in it; carcinogens, tumor promoters, heavy metals |
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Term
In cells, what determines the specificity of responses to chemical messengers? |
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Definition
Past developmental history; ie, Ach in muscle and secretory cells |
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Term
Can membrane bound receptors span the membrane only once or several times? |
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Definition
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Term
How do you measure small molecule, peptide hormone and growth factor ligand levels? |
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Definition
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Term
What can you determine about membrane receptors by using binding assays? |
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Definition
Number of receptors per unit tissue, and the affinity constant for the receptor-ligand interaction |
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Term
True or False: Ligand binding rarely activates intracellular protein kinases. |
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Definition
False, often causes ligand-induced phosphorylation of intracellular enzymes, transcription factors, etc. |
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Term
What are the 3 ways which ligands can activate protein kinases by binding to receptors? |
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Definition
Elevation of cAMP to activate cAMP-dependent protein kinases, elevation of diacylglycerol(DAG) to activate protein kinase C, elevation of calcium to activate calcium-calmodulin PK |
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Term
Elaborate on the activation of cAMP dependent protein kinase. |
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Definition
Ligand binds receptor, receptor releases G-(alpha)-protein which binds to GTP, G-protein complex binds adenyl cyclase, adenyl cyclase uses ATP to generate cAMP, cAMP activates PK, G-protein creates GDP from GTP |
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Term
How does cAMP specifically activate protein kinase-A? |
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Definition
2 cAMPs bind the 2 regulatory units releasing 2 catalytic subunits |
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Term
Is there signal amplification at nearly all steps of the cAMP signal transduction pathway? |
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Definition
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Term
What is phosphodiesterase? |
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Definition
The enzyme that decompses cAMP to AMP |
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Term
What are two ways that you can potentiate(increase) the level of cAMP? |
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Definition
Inhibiting phosphodiesterase which breaks it down, or by activating the G-protein irreversibly |
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Term
How can the same hormone stimulate different responses in two cell types? |
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Definition
The substrates for PKA differ in cells, and there exist large number of alpha, beta, gamma subunit genes which make for a large combination of reactions |
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Term
How does PKA activate transcription of selected genes? |
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Definition
cAMP response element binding proteins get phosphorylated by PKA activating it as a transcription factor |
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Term
True or false: Dopamine, adenosine, and prostaglandin E1 hormones exaggerate cAMP production in cells. |
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Definition
False. Their receptors release an inhibitory G-protein which inactivates adenyl cyclase |
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Term
How is the signal molecule diacyl glycerol DAG created? |
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Definition
Hormone-receptor complex releases a G-alpha-protein subunit, stims PPI-PDE, cleaves PIP2, releases DAG |
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Term
How is protein kinase C (PKC) stimulated? |
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Definition
In the presence of calcium and phospholipids, DAG heightens current low stimulation to high |
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Term
How does the calcium-calmodulin pathway work? |
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Definition
Ligand(histamines) bind receptor, calcium channel opens, 4 Ca bind calmodulin, calmodulin binds CAM-kinases |
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Term
List the secondary messengers for all 3 protein kinases: PKA, PKC, CAM kinase. |
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Definition
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Term
What is another description of a protein kinase? |
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Definition
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Term
Do the following membrane receptors use secondary messenger signals: epidermal growth factor, insulin, platelet derived growth factor, colony stimulating factor. |
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Definition
NO, these receptors are enzymes(protein kinases) |
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Term
What is the main difference between membrane receptor enzymes and enzymes that rely on a signal pathway? |
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Definition
The protein kinases(enzymes) that use a signal pathway are subject to signal amplification |
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Term
What is the difference between secretory diarrhea and osmotic diarrhea? |
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Definition
Secretory is the loss of fluids due to cotransport of solutes and fluid, osmotic is that there is a high concentration of solutes outside the intestinal lumen creating osmotic pressure and driving water out |
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Term
What is the main source of ROS? |
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Definition
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Term
What injurious effects on a cell can an increase in cellular calcium have? |
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Definition
increases the activities of enzymes like ATPase, phospholipase, and others so increase internal degradation of needed chemicals (ATP) and proteins. |
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