Term
Selectivity 1) What is it 2) 2 components of it |
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Definition
1) Increasing probability of obtaining beneficial effects and minimizing the probability of negative effects 2) Dose- as dose increases, selectivity decreases. Time- how often, how it gets into body, how well it gets rid of drug |
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Term
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Definition
Study of drug effects on the body. Dose-response relationships and drug interaction with receptors |
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Term
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Definition
Study of the body's effects on the drug. How the drug travels through the body. Related concepts: time-action relationship, drug absorption, distribution, biotransformation and elimination |
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Term
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Definition
Measure of the strength between the drug molecule and its binding site on the receptor. |
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Term
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Definition
ability to cause the receptor the change to the active state |
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Term
Give the relative efficacy and affinity of each type of drug: agonist, competitive antagonist, partial agonist |
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Definition
agonist: affinity; efficacy=1 comp antagonist: affinity; efficacy=0 partial agonist: affinity; efficacy is 0 |
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Term
equilibrium dissociation constant KD |
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Definition
the concentration of drug at which half the receptors are bound when the system has reached equilibrium |
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Term
ED50. What does ED50 represent in quantal dose response curves |
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Definition
the agonist concentration when E/Emax is 0.5 (half maximal effect). In a quantal curve, the dose at which half the population responds |
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Term
Describe the concept of spare receptors |
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Definition
Maximum response can be obtained with <100% receptor occupancy due to transduction amplification. |
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Term
Effect of increasing affinity/potency and effect of increasing efficacy on the dose-response curve |
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Definition
affinity/potency affect the position of the curve on the x-axis. More potent drugs are closer to the origin. Efficacy is reflected by the maximum effect produced; the ceiling of the curve. Higher efficacy drugs have a larger maximum |
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Term
How does the addition of a competitive antagonist/non-competitive antagonist affect the dose-response curve |
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Definition
Competitive agonist: behaves as a decrease in affinity/potency. Noncompetitive agonist: behaves as a decrease in efficacy. |
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Term
Describe graded vs quantal dose-response curves. |
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Definition
Graded: how much effect did this dose of drug cause in a patient. Quantal: Did this dose of drug have an effect in the patient; what is the probability this dose will produce the effect in someone? |
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Term
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Definition
Median toxic dose and median lethal dose. Dose at which 50% of the population reports toxic/lethal effects |
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Term
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Definition
TD50/ED50. LD50 can be used instead of TD50. |
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Term
Describe the subunit structure of the insulin RTK. How does this differ from other RTK |
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Definition
2 a-chains containing hormone-binding sites. 2 beta chains that cross the membrane and contain TK domains. Most RTK have a single transmembrane alpha-helix divided into intracellular/extracellular domains |
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Term
Describe the binding/activation of the insulin RTK. First molecule modified? |
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Definition
2 insulin molecules required to activate fully. Binding induces autophosphorylation stimulating tyrosine phosphorylation of the IRS-1 protein |
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Term
2 pathways mediated by IRS-1 |
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Definition
1. Growth pathway: IRS phosphorylates Shp --> Ras --> MAP kinase cascade --> transcripting factors that control growth promotion.
Glucose uptake pathway: IRS-1 phosphorylates P13K, initiating a phos cascade that eventually leads to GLUT 4 transporter placement in the plasma membrane |
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Term
CML and how it relates to TRK processes. |
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Definition
Bone marrow malignancy. 20% of all leukemias, always fatal. 90% have a philadelphia chromosome translocation that results in production of the aberrant fusion protein Bcr-Abl. This protein is dysregulated resulting in constitutive activation of the Growth Pathway mediated by IRS-1 phosphorylation leading to unregulated growth. |
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Term
What molecule is erroneously produced during CML and what is its normal function |
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Definition
Bcr-Abl is produced; Abl is normal and tightly regulated. Bcr-Abl is a piece of shit that results in activation of the Ras-MAP kinase pathway and unregulated growth |
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Term
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Definition
Selectively binds and inactivates Bcr-Abl, mitigating CML |
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Term
B-raf and the significance of its mutation |
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Definition
B-raf is a Serine/Threonine Kinase that regulates the MAP Kinase pathway. 50% of melanoma patients have a mutation resulting in constitutive activity. |
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Term
3 Major Classes of G Protein Linked Receptors |
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Definition
cAMP (Gs/Gi), Phospholipase C (Gp/Gq...DAG/IP3/Ca2+), Rhodopsin (Gt...cGMP) |
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Term
cAMP dependent Protein Kinase 1) Receptor structure 2) Effects of binding 3) How does reversal/moderation of response |
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Definition
1) The receptor is a tetramer with 2 cAMP binding chains and 2 catalytic chains. 2) Binding causes release of activated catalytic subunits. Catalytic Units phosphorylate various enzymes. 3) Dephosporylation of substrates/ degradation of cAMP by phosphodiesterase |
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Term
Describe the effect of cAMP levels on glycogen synthase. What protein does cAMP activate? What is the result of this activation? |
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Definition
Increasing cAMP levels inactivate glycogen synthase
PKA is activated by cAMP, resulting in a phosphorylation cascade: PKA --> phosphorylase kinase --> glycogen phosphorylase --> glycogen to G1P and glycolysis |
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Term
Gi- subunits, activity on adenylate cyclase |
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Definition
Gi has B and g subunits like gs but also an ai subunit that binds and hydrolyzes GTP, and inactivates AC activity |
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Term
Effect of epinephrine on B and a2? What organs are associated with each? |
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Definition
Fight or flight response B- heart- vasodilation A- peripheral organs- vasoconstriction |
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Term
Describe the Gq protein of Ca2+/Phosphoinositide pathway |
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Definition
Gq similar to Gs. aq subunit interacts with the receptor and activates effector enzymes. B/g dimer anchors Gq to the plasma membrane |
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Term
Describe the process of activating Gq in the Ca2+/Phosphoinositide pathway. What 2nd messengers are produced? |
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Definition
GTP bound Gq activates PLC. PLC cleaves PIP2 to yield DAG and IP3. |
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Term
DAG/IP3 functions and solubilities |
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Definition
Lipophilic DAG activates PKC leading to an intracellular phosphorylation cascade. IP3 moves to the cytoplasm to trigger Ca2+ release leading to Ca2+/calmodulin cascade |
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Term
DAG/IP3 pharmaceutical mimics |
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Definition
Calcium ionophores- IP3 Phorbol esters- DAG |
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Term
The results of the Ca2+/phosphoinositide signalling pathway: What are the effects of ACh binding on MLCK/NOS? |
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Definition
ACh binding--> increase in Ca2+--> PKC activation.
Activation of MLCK- phosphorylates myosin causing actin interaction and muscle contraction. Activation of NOS produces NO causing relaxation of smooth muscle and vasodilation |
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Term
Effect/mechanism of NO on myosin light chains |
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Definition
NO activates sGC- soluble guanylate cyclase, increasing cGMP, causing dephosphorylation of MLC causing relaxation and vasodilation. |
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Term
Effect of nitrovasodilators and phosphodiesterases on the NO/cGMP pathway |
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Definition
Nitrovasodilators- activate sGC. PDE block response by converting cGMP to inactive 5'-GMP |
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Term
Location of PDE 5/3? What is the effect of viagra on each? |
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Definition
PDE 5- corpora cavernosa PDE 3- heart PDE 6- eye PDE 5 has 4600x selectivity over PDE 3 and 10x selectivity over PDE6. Viagra side effect= blurred vision |
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Term
Two step model of steroid receptor activation |
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Definition
1. Liganded receptor recruits CoA, which has histone acetyl transferase activity 2. Acetylation leads to unwinding of chromatin allowing binding of transcription factors (Pol II) |
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Term
Name the 3 domains of the steroid/thyroid receptor family gene |
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Definition
1. Transcription activation domain- promotes DNApoly activity 2. DNA-binding domain- interacts with promoter on gene DNA 3. Ligand-binding domain- binds steroid hormones |
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Term
Regarding the human genome- how many steroid/thyroid receptors are orphan receptors? How many nuclear receptors are contained? |
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Definition
30, including err1, err2, hap. Genome has 48 nuclear receptor genes. |
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Term
Adopted orphan receptors. How are orphan receptors analyzed? |
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Definition
bind dietary lipids. The implication is that they are involved in metabolism. Reverse endocrinology allows determination of function. |
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Term
PPARg. What are they being used as a therapeutic target for? |
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Definition
Peroxisome Proliferator-Activated Receptor. Drugs pioglitazone and rosiglitazone target them and are used to treat type 2 diabetes |
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Term
What are the effects of insulin on adipose and on muscle/liver? How is redistribution of fatty acids useful to treating diabetes? |
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Definition
Insulin promotes glucose uptake as glycogen in the liver and muscle. It inhibits lipolysis in adipose, which reduces serum FFAs. Excess FFAs can build up in muscle/liver leading to desensitivity and hyperglycemia. FFAs are best distributed into adipose, which is achieved through PPARg activation |
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Term
Location, method of activation and function of PPARa, PPARg, PPARd |
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Definition
PPARa- liver/muscle. Activated by fatty acids and fibrate drugs. Hypolipidemic actions- promote FFA uptake and B-oxidation. PPARg- expressed in muscle, liver, adipose and bone. Activated by FA, rachidonic acid derivative and TZD (anti diabetes drugs). PPARg have insulin sensitizing actions- they promote adipocyte differentiation, lipogenesis and storage. Promote glucose uptake in liver and muscle. More valuable drug target PPARd- ubiquitous but low abundance. Little known; similar to PPARg |
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Term
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Definition
Pioglitazone and rostiglitazone, anti-diabetic drugs that target PPARg and have insulin-sensitizing effects |
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Term
LXR- expression locations, activation, effect |
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Definition
Liver X Receptor- a cholesterol sensor expressed in liver, adipose, kidney, intestine and macrophages. Activated by cholesterol metabolites like oxysterols. Control homeostasis of cholesterol- transport, catabolism, excretion |
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Term
FXR- expression locations, activation, effect |
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Definition
Farnesoid X Receptor. Bile acid sensor. Expressed in liver and intestine, activated by bile acids and control efflux/excretion. |
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Term
How do LXR/FXR affect each other |
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Definition
Combined effect is to promote cholesterol excretion. LXR- promote cholesterol efflux into liver for metabolism or into the intestine for excretion. FXR- bile acid synth, efflux of bile into the pooper to be pooped out |
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Term
Regarding drug transport through pores. What organs are pores most important in? What drugs are dependent on pores? What is the driving force for transport via pores? |
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Definition
The nephron, but are the most important mechanism for entry of drugs into most tissues. Quaternary ammonium drugs. Water/hydrostatic pressure |
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Term
Finish the statement: The rate of entry of the drug into most tissues is not limited by ________ but by ________ |
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Definition
Lipid solubility, blood flow |
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Term
What organs does active transport take place? 2 major classes? |
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Definition
Proximal tubule, hepatocytes, GI tract; BBB, Choroid plexus, etc. 2 major classes are ABC and SLC |
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Term
Name the families in the SLC superfamily. What type of reactions? |
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Definition
Uniport/facilitated transport, and secondary (anti/sym-port). Families include the organic cation transporter (OCT), Multidrug and toxin extrusion (MATE), OCTN, and Organic Anion Transporters (OAT) |
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Term
OCT Family of transporters- type of molecules? Type of transport? What direction across cell membrane? Where does energy come from? |
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Definition
Transport of cations via facilitated transport/uniport. Electrochemical gradient is inwards, so OCTs mediate influx. Energy from NA/K ATPase |
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Term
MATE/OCTN Family of transporters- type of molecules? Type of transport? What direction across cell membrane? Where does energy come from? |
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Definition
Electroneutral drugs. Antiport with H+. Transport depends on pH gradient- this is an efflux pathway for cations. Na/H antiport simultaneously maintains the H+ gradient. NaK ATPase maintains the Na gradient. Na higher extracellularly. |
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Term
OAT Family of transporters- type of molecules? Type of transport? What direction across cell membrane? How is the increased intracellular negative charge justified? Where does energy come from? What organ is important |
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Definition
Influx of anions. OAT2 is for Nucleotides. OAT1/3 are for low MW anions, drugs, PGE2, urate. Influx of anions is not favored- so coupling with efflux of alpha-ketoglutarate results in net efflux of negative charge. akg is replenished via symport with Na+ via NaDC3. Energy comes from NaK ATPase. OAT is important in the liver |
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Term
How is energy acquired by ABC transporters? What is their function? What transporters are in the ABC transporter family? What type of transport is performed by each? |
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Definition
ATP is directly hydrolyzed. They pump drugs out of cells. P-glycoprotein transports large neutral or positive hydrophobic drugs (drugs that enter via passive diffusion). Multidrug resistance protein2 (MRP2) transports amphiphilic organic anions, esp glucuronide, glutathione and SO4. Breast Cancer Resistance Protein transports neutral/negative charged drugs, SO4 conjugates. |
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Term
What is the significance of active transport in the brain, choroid plexus, nephron and liver/GI? |
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Definition
Brain/choroid- protect tissue Nephron- excretion Liver/GI- absorption/elimination; biotransformation, transport into bile/blood |
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Term
What type of drugs are absorbed in the stomach |
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Definition
Weak acids. Insignificant |
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Term
Metabolism of drugs first pass through GI system? Significance of the hepatic portal vein? |
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Definition
P-glycoprotein transports back into lumen; metabolism in gut. All drugs absorbed from the GI tract pass through the hepatic portal vein before entering systemic circulation |
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Term
What is bioavailability? How does this relate to the first pass effect? When is 0 bioavailability useful |
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Definition
Bioavailability is the fraction of unchanged drug that reaches the systemic circulation (metabolism in liver/GI tract/excretion in shit). Drugs with a high 'first pass' effect have very low bioavailability. 0 bioavailability is useful if metabolites are active. |
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Term
Describe a mechanism to increase the bioavailability of a normally low BA drug |
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Definition
Drug interaction- add a drug that occupies metabolizing enzymes that process the original drug |
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Term
What % of drug enters systemic circulation via sublingual/rectal administration |
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Definition
Sublingual- 100 Rectal- 50 |
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Term
Pros/Cons of IV drug administration |
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Definition
Pro: Rapid, best control Con: Concentration rises rapidly; need to inject slowly. Vein damage from repeat dosing. Drug must be aqueous. Non reversible |
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Term
Pros/Cons of IM drug administration. How are drugs absorbed into the bloodstream? |
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Definition
Absorption through capillary pores/lymphatic system. Pro: Fairly rapid absorption, can provide slow sustained absorption of poorly water soluble drugs in oil. Con: pain/hematoma, can't use with anticoag therapy |
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Term
Pros/Cons of SC drug administration |
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Definition
Absorption through capillary pores/lymphatic system. Pro: rapid, sustained effect/solid pellet insertion. Con: certain drugs irritate the tissue. |
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Term
What types of drug are supplied topically? |
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Definition
Local effect/minimize exposure. Some are applied in patches for slow, systemic supply. Drugs applied topically need to be potent and have a very favorable PC |
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Term
Describe the structure of the BBB that makes it so difficult to penetrate pharmaceutically. How do drugs pass the BBB? |
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Definition
Capillaries have tight junctions instead of pores, and are surrounded by glial cells. They also contain drug transporters (p-gp) that extrude drugs. Drugs reach the CNS via passive diffusion across 4 lipid bilayers. A very favorable PC is required. Inflammation increases capillary permeability. Certain areas of the brain (chemoreceptor trigger zone/hypothalamus) lack the BBB |
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Term
Location and structure of the Blood-CSF barrier? How do drugs penetrate the Blood-CSF barrier? What is the relative area of the blood-CSF barrier? |
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Definition
The choroid plexus is in the lateral, 3rd and 4th ventricles. The cells of the choroid plexus are connected by tight junctions- the BCSFB. Drugs pass through the Blood-CSF barrier by passive diffusion across the epithelia. The area is 1/1000 of the BBB. Has drug metabolizing enzymes and active transporters. |
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Term
Describe the structure of the placental barrier. What types of drugs cross? What |
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Definition
No pores; but only large/multiple charge drugs do NOT cross. Lipophilic drugs enter circulation readily via simple passive diffusion. The fetal blood is more acidic- basic drugs may accumulate here preferentially. P glycoprotein present. |
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Term
2 other organs with no pores |
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Definition
Synovial membrane, testes/prostate |
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Term
How do plasma binding proteins affect multi drug interactions |
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Definition
Addition of a second drug causes a transient increase in the first drug because of displacement on plasma binding proteins. Transient because the drug is excreted more quickly. |
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Term
Diseases that lead to decrease in levels of plasma proteins (2). How do these diseases affect drug concentration? |
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Definition
1. Severe liver disease- albumin synthesized in the liver. 2. Renal disease- proteinuria. Increase in free drug concentration due to less bound drug |
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Term
Diseases that lead to increase in plasma binding proteins? Effect on drug concentration? |
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Definition
Cancer/arthritis/Crohn's, MI- diseases that induce acute phase response |
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Term
Renal filtration- what molecules are filtered? What molecules are reabsorbed? What is the filtration fraction? How does drug concentration change/dissociate from binding proteins upon filtration? |
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Definition
All molecules <50kD in weight are filtered. Useful molecules are reabsorbed. 1% of filtered volume ends up in the bladder. Filtration fraction= amount of drug filtered dependent on renal blood flow (normally 20%, lower in old/young/renal disease). Concentration of drug in unfiltered fraction doesn't change since water is also filtered- no dissociation from albumin. |
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Term
Active Tubular Secretion- Describe the flow of charged drugs from the capillaries to the lumen of the convoluted tubule. How does this process affect protein binding proteins in the blood? |
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Definition
Movement through pores from blood into interstitium. Active transport from interstitium into tubule cells. Exchange systems into lumen of tubule. As free concentration of drug in the interstitium falls, free drug in capillary diffuses lowering capillary conc --> drug dissociates from proteins. |
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Term
Cation Secretion of the kidney tubule cells. Describe the transporters in the basolateral and apical membrane. |
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Definition
Basolateral: OCT2/3 import drugs with net increase in positive charge moving intracellularly. This is driven by the membrane potential produced by the Na/K pump. Apical membrane: MATE1/MATE2-K SLC transporters mediate efflux by electroneutral cation/H+ exchange (H+ flows into cell, cation into lumen). Apical membrane: MDR/P-glycoprotein pumps cation into lumen by hydrolyzing ATP. H+/Na+ pump removes H+ pumped into the lumen by MATE and provides substrate for the NaK ATPase. |
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Term
Anion Secretion of the kidney tubule cells. Describe the transporters in the basolateral and apical membrane. |
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Definition
Basolateral domain: Uniport not feasible, need antiport with aKG (OAT1/OAT3). Net flux of negative charge is out of the cell, which is favorable. NaDC3 transports aKG back into the cell via symport with 2Na+. Na+ conc is justified by the efflux action of NaK ATPase. Apical domain: MRP2/MRP4 (ABC transporters) transport anions into the lumen via hydrolyzation of ATP |
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Term
Regarding the nephron: describe the factors that promote formation of a gradient for drug reabsorption. |
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Definition
Salt/water are actively reabsorbed during passage through the nephron. Drugs in the urine become concentrated and diluted in the plasma. This generates a gradient for reabsorption |
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Term
What types of drugs are reabsorbed by the nephron? What does the rate of reabsorption depend on? What other factors affect amount of drug reabsorbed? |
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Definition
Neutral drugs; or weak acid/weak base with a favorable partition coefficient. Rate depends on partition coefficient, pK and pH. Amount reabsorbed decreases when volume/flow increase. |
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Term
What factors contribute to drug precipitation in the tubule? |
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Definition
Volume of water decreases dramatically as urine flows through a tubule. Low water soluble drugs may precipitate out |
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Term
Describe the properties of inulin that lead to its simple excretion process |
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Definition
It is small, uncharged (no active secretion), has a PC of 0 (not reabsorbed) and does not bind plasma proteins (Filtration fraction = fraction filtered = 20%). Amount in urine dependent only on GFR. |
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Term
Describe the properties of penicillin G that affect its excretion process |
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Definition
Small enough to be filtered, weak acid so active secretion is very efficient (90%), 60% bound to plasma proteins and 40% free (20% filtration fraction x 0.4 = 8%) and its partition coefficient is 0 so it is not reabsorbed. Half life is very short- 30 minutes. Its not reabsorbed so its excretion is not pH dependent. |
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Term
Describe the properties of probenicid that affect its excretion process |
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Definition
Small MW, 10% free so filtration fraction is 20% x 0.1 = 2%. Anion is actively secreted which competes with other anions (penicillin). PC very favorable so it is reabsorbed almost completely in distal tubule. Blocks secretion by competition and has a long half life (5-8 hours) |
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Term
What weight of drugs are filtered by the kidney? What type of particles are actively transported? What type of particles are reabsorbed? How does excretion change with age/disease |
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Definition
< 50kD MW. Net +/- charge are substrates for active transport in proximal tubule. Weak acids/bases will undergo reabsorption in the distal nephron in a pH-dependent manner. GFR decreases with age/renal disease so dose is lowered. Plasma drug conc increase, t1/2 increases, toxicity increases. |
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Term
Phases of biotransformation and what each phase accomplishes. Most important site? |
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Definition
Phase I: Oxidation/hydrolysis/reduction to make drugs more water soluble. Phase II: Conjugation. Increases solubility, provide negative charge, attach to hydrophilic substance, lower PC, inactivate drug. Results in less binding to albumin, more filtering, producing a substrate for anion pumps so more is secreted, less reabsorption in the kidney, more efficient elimination. Most important site is the liver. |
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Term
Cytochrome P450- location? effect? required coenzymes? 3 P's? Most active families in the liver? |
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Definition
Located in SER. Oxidizes liphophilic substrates using a heme iron-O2 complex while reducing water to H2O- 'mixed function.' Requires electrons from NADPH-P450 reductase. P450s are Pink in the presence of CO abs Peak at 450 nm. Most active families are CYP2D6 and CYP3A4. |
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Term
4 Major types of P450 Oxidation? These are all phase 1 reactions. |
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Definition
1. Hydroxylation of aliphatic/aromatic carbons. 2. Deamination/N-dealkylation. Produces an amine/ammonia and a keto compound. 3. O-dealkylation. Oxidation of the carbon attached to O in an ether produces an alcohol and keto compound. 4. N-oxidation/S-oxidation. Direct addition of an oxygen. |
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Term
3 Phase 1 hydrolysis reactions. Where are the enzymes located? Which can activate a drug? |
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Definition
1. Epoxidide Hydrolase (Epoxides produced by CYP)- turns epoxide to a diol. Enzyme in the microsome. 2. Esterase. Hydrolyze esters into acid + alcohol. Found in the ER/cytosol. Can activate a drug. 3. Amidase- hydrolyze amides to an amine and an acid |
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Term
2 drugs activated by conjugation? |
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Definition
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Term
Name the 5 conjugation reactions |
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Definition
1. Glucuronidation, Sulfation, Glutathione conjugation, N-acetylation, Methylation |
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Term
Glucuronidation. What enzymes? Where are these enzymes found? How does glucuronidation facilitate excretion? |
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Definition
UDP-glucuronosyltransferases in the ER esp liver/GI tract. Glucuronidation increases water solubility and provides a negative charge. This results in less albumin binding and more glomerular filtration. The product becomes an anion pump substrate and cannot undergo reabsorption. |
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Term
2 families of UDP-glucuronosyltransferases? What is each used for? |
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Definition
UGT-1: bilirubin conjugation. 9 genes. UGT-2: 10 genes; for endogenous substrates like steroids |
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Term
Gilbert's Syndrome? Crigler-Najjar Syndrome |
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Definition
Both are UGT-1 mutations associated with jaundice. Gilbert's syndrome causes an increase in plasma bilirubin and increases risk of drug interaction. Caused by promoter mutation. C-N: no active UGT1A1. No bilirubin conjugation and early death |
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Term
Sulfotransferase enzymes- function? Substrate? What types of drugs do they affect? Role in xenobiotic processing? |
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Definition
Sulfotransferase enzymes add SO4 from 3-phosphadenosine-5'phosphosulfate (PAPS). Primarily add to Ar-OH but also R-OH/R-NH2. Functions on endogenous substrates (sterols) but also on xenobiotics in the liver and intestine |
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Term
Glutathione conjugation. Describe the glutathione molecule. What types of substrates does it act on? |
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Definition
The glutathione molecule has a reactive thiol attached to a g-carboxyl group. Reacts with oxidative substances which yields a glutathione GSSG dimer |
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Term
Glutathione reductase, Glutathione-S-transferases |
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Definition
Glutathione reductase uses NADPH to reduce oxidized glutathione (GSSG). GST is the enzyme that mediates conjugation |
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Term
Regarding n-acetylation. What group is transfered? Effect on the substrate? What enzyme catalyzes this? Slow/fast acetylaters? |
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Definition
An acetyl group is transfered from acetyl-CoA to an aromatic amine/hydrazine group. Polarity is decreased, weird. NAT1 family is ubiquitous, NAT2 is in liver/GI. Slow/fast acetylaters refer to the bioavailability of acetyl CoA. Slow acetylaters can have SLE. |
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Term
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Definition
N-oxidation yields toxic NAPQI. GST conjugation produces a nontoxic metabolite. Glutamate and glycine are removed from the glutathione and the remaining cysteine is N-acetylated. N-acetylcysteine is supplied to prevent toxicities. |
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Term
What two conjugation reactions decrease polarity? |
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Definition
N-acetylation, methylation |
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Term
Methylation: what group is transfered? What enzymes? |
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Definition
Methyl group from SAM to O/N/S atoms. Many methyltransferases exist for various substrates. |
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Term
Azathioprine. How is it activated? What is it activated to? |
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Definition
Pro drug metabilized by TPMT, a methylating enzyme. It becomes 6-mercapto-purine which is incorporated into DNA and stops replication. Used for immune suppression/chemo. |
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Term
How do drugs reach the liver from the GI tract/body? Two fates of drugs after being processed by hepatocytes? |
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Definition
GI--> HPV body--> HA. The drugs can go to systemic circulation and be excreted by the kidney or can go into bile caniculus/gallbladder to be released into SI with bile. |
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Term
Describe the influx of drugs in the hepatocyte and the efflux to the blood and bile |
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Definition
Influx: OCT/OAT transporters driven by Na/K ATPase. Efflux into bile by ABC transporters in the canicular membrane- P-gp, MRP, BRCP driven by ATP hydrolysis. Efflux into blood by MRP in sinusoidal membrane driven by ATP hydrolysis. |
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Term
Following biliary excretion, what are (3) possible pathways a drug can follow |
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Definition
1. Poor PC drugs remain in GI and are shat out. 2. Good PC reabsorbed and pass back to liver via blood. 3. Enterohepatic cycling: Glucuronic acid conjugated drugs have a very unfavorable PC but can be cleaved. The released drug can pass through to the liver if it has a good PC. |
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Term
Consequences of enterohepatic cycling? |
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Definition
Half life prolonged and eventual excretion by kidney. Agents that block enterohepatic cycling by preventing reabsorption can dramatically decrease half life- antibiotics that kill bacteria; non-absorbable polymers |
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