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General Pharmacology, part 2 Pharmaco-dynamics & Medication Administration

Explore how drugs interact with receptors, the importance of medication safety, and drug classifications based on mechanisms of action. Learn about drug distribution, biotransformation, and factors affecting drug response.

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General Pharmacology, part 2 Pharmaco-dynamics & Medication Administration

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  1. General Pharmacology, part 2Pharmaco-dynamics &Medication Administration • F ‘08 • P. Andrews

  2. Pharmacodynamics • Most drugs bind to a receptor • Protein molecules • Can be stimulated/inhibited by chemicals • Each receptor’s name generally corresponds to the drug that stimulates it • Affinity • Force of attraction between a drug and a receptor • Different drugs may bond to same receptor site, but strength of bond may vary – binding site’s shape determines receptivity to chemicals

  3. Drug’s pharmacodynamics involves its efficacy • Generally, drugs either stimulate or inhibit the cell’s normal actions. • Efficacy and affinity not directly related • Drug A causes a stronger response than drug B • Drug B binds to the receptor site more strongly than drug A

  4. When drug binds to receptor, chemical change occurs • Drugs • Interact with receptor and result in desired effect • Interact with receptor and cause release/production of a second compound

  5. Giving medications safely • Know: • Indications • Contraindications • Precautions • Practice proper technique • Observe & document • Take careful drug histories

  6. Remember the 6 rights of medication administration! • Right • Person • Drug • Dose • Time • Route • Documentation • And - refusal

  7. So…. What happens anyway?

  8. Cells talk to each other • Three distinct languages • Nervous system • neurotransmitters • Endocrine system • hormones • Immune system • cytokines

  9. In disease, all systems are affected • The three systems can’t exist without each other • The actions of one impact the actions of the others • I.e., stress (nervous system) disrupts endocrine system which may respond with glucocorticoid production = suppressed immune response

  10. Drugs have class

  11. Drug Class Examples • Nitroglycerin • Body system: “Cardiac drug” • Action of the agent: “Anti-anginal” • Mechanism of action: “Vasodilator” • Indications for nitroglycerin • Cardiac chest pain • Pulmonary edema • Hypertensive crisis • Which drug class best describes this drug?

  12. Another way to classify drugs • Mechanism of Action • Drugs in each category work on similar sites in the body and will have similar specific effects/side effects • Beta blockers: metoprolol • ACE inhibitors: lisinopril • Alpha blockers: prazosin • Calcium-channel blockers: verapamil • Example: beta blocker actions and impacts • Suppress the actions of the sympathetic nervous system • Prehospital administration of epinephrine may not produce as dramatic effects with a patient taking a drug in this class

  13. Prehospital example: Hyperglycemics • Dextrose 50% and glucagon • Both will raise blood glucose • Mechanism of action • Glucagon: hormone that works in the liver to convert stored chains of carbohydrate to glucose • Dextrose 50%: ready-made simple sugar that is ready to enter into the cell • Which drug is considered first-line for hypoglycemia? Why? • What are some limitations for glucagon in the presence of severe hypoglycemia?

  14. Distribution • Some drugs bind to proteins in blood and remain for prolonged period • Therapeutic effects due to unbound portion of drug in blood • Drug bound to plasma proteins can’t cross membranes • Changing blood pH can affect protein-binding action of drug. • TCA’s are strongly bound to plasma proteins.

  15. Drugs bind to proteins • Albumen is one of the chief proteins in the blood available for binding with drugs. • When a pt. Is malnourished, albumen is low. • What significance does this have re; drug therapy?

  16. The blood – brain barrier • Tight junctions of capillary endothelieal cells in CNS form a barrier • Only non-protein-bound, highly lipid-soluble drugs can enter CNS • Placental barrier similar

  17. Other deposits • Fatty tissue serves as drug reservoir • Bones and teeth can accumulate drugs that bind to calcium • Ie., tetracycline

  18. Ok, you’ve given the drug – now what?

  19. Biotransformation • Drugs are metabolized – broken down into metabolites • Transforms drug into more or less active metabolite • Make drug more water soluble to facilitate elimination • Protein-bound drugs are not available for biotransformation

  20. Biotransformation, cont. • Occurs in liver primarily • Also occurs in kidney, lung, GI tract • First-pass effect • Some drugs can’t be given orally

  21. What alters drug response? • Age • Body mass • Sex • Environmental • Time of administration • Pathologic state • Genetic factors • Psychological factors

  22. Drugs that change physical properties • Osmotrol • Drugs that chemically bind with other substances • Isopropyl alcohol – denatures proteins on surface of bacterial cells • Drugs alter a normal metabolic pathway • Anticancer, antiviral drugs

  23. Response to drug administration • We must carefully weight risk vs benefit! • Allergic reaction • Hypersensitivity • Idiosyncrasy • Effect unique to person; not expected • Tolerence • Decreased response to drug after repeated administration

  24. It’s all about the cell….

  25. Brain sends out the response via nerve paths • Nerve moves the response: depolarization • Depolarization stimulates norepinephrine sacks • Sacks move to the end of the nerve and dump out their contents 2 3

  26. Norepinephrine travels across the synapse • Attaches to a receptor on the organ, organ responds to the signal • Norepineprhine detaches and is deactivated • 2 options: destroy it or move it back into its sack 5 2 3 4

  27. Now, how do we get rid of the drug?

  28. Elimination • Most drugs excreted in urine • Some in feces or air • Glomerular filtration • A function of glomerular filtration pressure (BP and kidney blood flow) • Active transport system; requires ATP • Tubular secretion • Urine pH affects reabsorption in renal tubules

  29. Elimination, cont. • Some drugs and metabolites are eliminated in expired air • Breathalyzer • Feces, sweat, saliva, breast milk

  30. Ok, so how do they get in our system?

  31. Drug Routes • Enteral • Oral (PO) • Orogastric/Nasogastric (OG/NG) • Sublingual (SL) • Buccal • Rectal (PR)

  32. Intravenous (IV) Endotracheal (ET) Intraosseous (IO) Umbilical Intramuscular (IM) Subcutaneous (SC, SQ, SubQ) Inhalation/ Nebulized Topical Transdermal Nasal Instillation Intradermal Drug routes, cont. Parenteral

  33. Drug forms • Liquid: (solute - solvent) - Solution • Tinctures: drug extracted chemically with alcohol. • Suspensions - liquid preparations don’t remain mixed • Spirits: Volatile chemicals dissolved in alcohol • Gaseous – Oxygen, Nitrous Oxide

  34. Emulsions: oily substance mixed with a solvent that won’t dissolve it. (oil and vinegar). • Elixirs: Drug in an alcohol solvent. (Nyquil) • Syrups: Drug dissolved in sugar and water (cough syrup). • Solids: capsule, tablet, lozenge, powder • Topical use: ointment, paste, cream, aerosol

  35. Other stuff you should know

  36. Drug storage • Properties may be altered by environment. • Temperature • Light • Moisture • Shelf-life

  37. Drug response relationship • Plasma level profiles • Length of onset, duration, termination of action, minimum effective concentration and toxic levels • Onset of action • A medication reaches it’s minimum effective concentration • Minimum effective concentration • Level of drug needed to cause a given effect

  38. Duration of action • How long the drug remains above it’s minimum effective concentration • Termination of action • Time from when a drug drops below minimum effective concentration until it’s eliminated • Therapeutic index • Ratio of a drug’s lethal dose for 50% of population to its effective dose for 50% of population • Half-life • Time the body takes to clear one half of the drug

  39. Cross tolerence • Tolerence for a drug that develops after administration of a different drug • Tachyphylaxis • Rapidly occuring tolerance to a drug • Decongestants, bronchodilators • Cumulative effect • Increased effectiveness when a drug is given in several doses

  40. Drug dependence • Pt becomes accustomed to drug; will suffer withdrawal symptoms • Drug interaction • Effects of one drug alters response to another drug • Drug antagonism • Effects of one drug blocks response to another drug • Summation • Additive effect; two drugs that both have same effect are given together

  41. Second messenger • Calcium or cyclic adenosine monophosphate (cAMP) • Most common second messenger • Activates other enzymes; cascading • Number of receptor sites on target cell constantly changes • Receptor proteins destroyed during function • Reactivated or remanufactured • Down regulation • Binding of a drug or hormone that causes number of receptors to decrease

  42. Synergism • Two drugs that have the same effect are given together and produce a response greater than the sum of their individual responses • Potentiation • One drug enhances the effect of another • Interference • One drug affects the pharmacology of another drug

  43. Summary

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