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Chapter 10 Principles of Pharmacology National EMS Education Standard Competencies Pharmacology Integrates comprehensive knowledge of pharmacology to formulate a treatment plan intended to mitigate emergencies and improve the overall health of the patient. National EMS Education Standard Competencies Principles of Pharmacology • Medication safety • Medication legislation • Naming • Classifications • Schedules • Pharmacokinetics National EMS Education Standard Competencies Principles of Pharmacology (cont’d) •Storage and security •Autonomic pharmacology •Metabolism and excretion •Mechanism of action •Phases of medication activity •Medication response relationships National EMS Education Standard Competencies Principles of Pharmacology (cont’d) •Medication interactions •Toxicity Introduction • Medication administration is a defining element of paramedic clinical practice. • Medications can have many desirable clinical effects. Introduction • Severe, often life-threatening consequences can occur if paramedics make a mistake. • Pharmacology is the scientific study of how various substances interact with or alter the function of living organisms. Historical Perspective on Medication Administration • Chemicals have been used for centuries. • Formal scientific study began in the 17th and 18th centuries. • Some ancient remedies are still used today. Historical Perspective on Medication Administration • Evidence-based guidelines assist clinicians using pharmacologic interventions. − Medications undergo extensive testing and clinical trials. Medication and Drug Regulation • The United States has a comprehensive system of medication and drug regulation. − The Food, Drug, and Cosmetic Act (1938) • The United States Food and Drug Administration (FDA) approves new medications and removes unsafe medications from use. Medication and Drug Regulation • Approval of a new medication typically takes years. − Some medications are used “off-label.” • A purpose not approved by the FDA • At doses different from the recommended doses • By a route of administration not approved by the FDA Controlled Substances Act of 1970 • Classifies certain medications with the potential of abuse into five categories (schedules) Sources of Medication • Synthetic − Made completely in a laboratory • Semisynthetic − Made from chemicals derived from plant, animal, or mineral sources Sources of Medication • Pharmaceutical companies control: − Concentration − Purity − Preservatives − Other ingredients • Medications must have a manufacturing lot number and expiration date. Forms of Medication Medication Names • Chemical name: used during development • Nonproprietary (generic) name: promotes consistency and avoids duplication − Includes a “stem” • Brand name: selected for marketing Medication Reference Sources • Consider: − Reliability − Printed, electronic, or both − Depth of information − − − − Accessibility Cost Availability of updates Size of materials used Medication Reference Sources • Medication monograph: medical profile − Unites States PharmacopeiaNational Formulary (USP-NF) − Physicians’ Desk Reference (PDR) Medication Reference Sources • Manufacturers provide package inserts. − Include information on: • Dosing • Route of administration • Contraindications • Adverse effects Medication Reference Sources • Hospital pharmacies often compile formularies specific to their needs. • AMA Drug Evaluations − Provides detail about medication selection and administration Medication Storage • Must provide adequate protection • Must be convenient for quick access • Must prevent physical damage • Should be placed in protective bins • Should facilitate quick and accurate identification Medication Storage • Avoid: − Direct sunlight − Extreme temperatures − Physical damage Medication Security • Controlled substances require: − Additional security − Additional record keeping − Disposal precautions Medication Security • Every last milliliter or milligram needs to be documented. • Controlled substances are often the target of tampering or diversion. − Inspect vials and ampules. Physiology of Pharmacology • Medications are administered to produce a desired effect in the body. • Pharmacodynamics: as a medication is administered, it alters a function or process of the body. − Any medication can cause toxic effects. Physiology of Pharmacology • Process of medication administration: − Absorption − Distribution − Biotransformation − Elimination • Pharmacokinetics: action of the body on a medication Principles of Pharmacodynamics • Receptor sites exist in proteins connected to cells. − Receptors are activated by: • Endogenous chemicals • Medications and chemicals Principles of Pharmacodynamics • When a medication binds with a receptor site: − Channels permitting the passage of ions in cell walls may be opened or closed. − A biochemical messenger becomes activated. − A normal cell function is prevented. − A normal or abnormal cell function begins. Principles of Pharmacodynamics • Medications are exogenous chemicals. • Medications bind with particular receptor sites of target cells. − Newer medications target only specific receptor sites. Principles of Pharmacodynamics • Two types of medications affect cellular activity by binding with receptor sites: − Agonist medications initiate or alter a cellular activity. − Antagonist medications prevent agonist chemicals from reaching cell receptor sites. Principles of Pharmacodynamics Agonist Medications • Affinity: ability of a medication to bind with a particular receptor site • Threshold level: level at which initiation of alteration of cellular activity begins − Increasing concentrations increase effects. • All receptor sites become occupied. • Maximum capacity of cell is reached Agonist Medications • Affinity: ability of a medication to bind with a particular receptor site − Agonist medications bind with receptor sites. Agonist Medications • Threshold level: level at which initiation of alteration of cellular activity begins − Increasing concentrations increase effects until: • All receptor sites become occupied. • Maximum capacity of cell is reached Agonist Medications • Potency: concentration of medication required to initiate a cellular response − As potency increases, the concentration or dose required decreases. • Efficacy: ability to initiate or alter cell activity in a therapeutic or desired manner Agonist Medications • Doseresponse curve − Illustrates the relationship of medication concentration and efficacy Antagonist Medications • Prevent cellular response to agonist chemicals. − Inhibit normal cellular activation. − Treat harmful agonist effects of exogenous medications. Antagonist Medications • Competitive antagonists − Temporarily bind with cellular receptor sites. − Efficacy is related to: • Its concentration near the receptor sites • Its affinity compared with the affinity of the agonist chemicals present Antagonist Medications • Noncompetitive antagonists − Permanently bind with receptor sites and prevent activation by agonist chemicals. − Effects continue until new receptor sites or cells are created. • Cannot be overcome by increased doses of agonist chemicals Partial Agonist Chemicals • Bind to receptor site − Do not initiate as much cellular activity as other agonists • Lower the efficacy of other agonist chemicals Alternative Mechanisms of Drug Action • Medications can alter cell function without interacting with receptors. − Engineered to target: • Microorganisms • Lipids • Water • Exogenous toxic substances Alternative Mechanisms of Drug Action • Antimicrobials − May target specific substances present in the cell walls of a bacteria or fungi • Chelating agents − Bind with heavy metals. − Sodium bicarbonate Alternative Mechanisms of Drug Action • Diuretics − Create osmotic changes. • Alter distribution of fluids and electrolytes. • Electrolyte-based medications − Change concentration and distribution of ions in cells and fluids throughout the body. Factors Affecting Response to Medications • Choice of medication • Dose • Route • Timing • Manner of administration • Monitoring Factors Affecting Response to Medications • Age − Percentage of body fat • Lowest in infants; increases in adults − Percentage of body water • Highest in newborns; decreases throughout life − Percentage of body proteins • Varies throughout life span Factors Affecting Response to Medications • Age (cont’d) − Consider titration of medication for pediatric or elderly patient. • Alteration of metabolism/elimination may prolong effects. • Patients at extremes of age are disproportionately prone to paradoxical medication reactions. Factors Affecting Response to Medications • Weight-based medication dosing − Quantity of medication is multiplied by the patient’s weight in kilograms. − Advantages: • Amount of medication is proportional to size of patient • Manufacturers have already calculated factors. • Can calculate appropriate dose for all ages Factors Affecting Response to Medications • Weight-based medication dosing (cont’d) − Limitations: • Need patient’s weight in kilograms • Does not consider alterations in distribution, metabolism, and elimination • Some medications are intended to be based on the patient’s ideal body weight. Factors Affecting Response to Medications • Environment − Hyperthermia • May increase metabolism of drugs • May reduce amount of drug returned to circulation − Hypothermia • Impairs effectiveness of medications used in traditional cardiac life support Factors Affecting Response to Medications • Genetic factors − Be careful when administering medications to patients with genetic disorders. • Primary pulmonary hypertension • Sickle cell disease • Glucose-6-phosphate dehydrogenase deficiency − Patients and family are good sources of information. Factors Affecting Response to Medications • Pregnancy − Many changes take place in the body: • Cardiac output and intravascular volume increase. • Hematocrit decreases. • Respiratory tidal volume, minute volumes increase. • Inspiratory/expiratory reserve volumes decrease. • Gastrointestinal motility decreases. • Renal blood flow and urinary elimination increase. • Endocrine glands undergo change. Factors Affecting Response to Medications • Pregnancy − Changes can affect the absorption, distribution, or elimination of medications. − Consider effect on the fetus. Factors Affecting Response to Medications • Psychosocial factors − Pain, anxiety, and discomfort can vary among individual patients. − Be alert for verbal and nonverbal cues. − Medication administration is complicated by the placebo effect. Types of Medication Responses • Therapeutic (desired) effects − Medication is selected based on patient’s: • Illness, injury, complaint, signs, symptoms − Condition should match “Use/Indication” listed on the medication profile. Types of Medication Responses • Therapeutic (desired) effects (cont’d) − Medication is administered in a dose intended to produce a desired clinical response. • Some require repeated dosing. • Capable of demonstrating cumulative action Types of Medication Responses • Adverse medication effects − Clinical changes that are not desired and cause harm or discomfort to the patient − Consider in relation to the patient’s condition • Patients with chronic medical conditions are more susceptible. • Patients may be unable to tolerate even mild adverse effects. Types of Medication Responses • Adverse medication effects (cont’d) − May range in severity − Can be desirable in certain situations and harmful in others − Can be completely unexpected • Idiosyncratic medication reactions Types of Medication Responses • Therapeutic index − Median lethal dose (LD50): dose that causes death in 50% of animals tested − Median toxic dose (TD50): 50% of animals tested had toxic effects at or above this dose − Median effective dose Types of Medication Responses • Therapeutic index (cont’d) − The relationship between the median effective dose and the median lethal dose • Large difference: medication is safe. • Small difference: patient needs to be monitored. Types of Medication Responses • Immune-mediated response − Genetically predisposed patients have an initial exposure/sensitization to an allergen. − Medication sensitivity may occur following the first exposure to a medication or substance. • Avoid administering medications to patients who have had a serious reaction to the medication . Types of Medication Responses • Medication tolerance − Certain medications have a decreased efficacy when taken repeatedly. • Tolerance results from down-regulation. Types of Medication Responses • Medication tolerance (cont’d) − Cross tolerance: repeated exposure within a particular class has the potential to cause a tolerance to the class. − Tachyphylaxis: repeated doses within a short time rapidly cause tolerance. Types of Medication Responses • Medication abuse and dependence − Prone to misuse and abuse: • Stimulants • Depressants − Repeated exposure can cause habituation. − Prolonged or significant exposure can cause dependence. Types of Medication Responses • Medication interactions − Medication interference: undesirable medication interactions − Major concern: incompatibility during administration − Medication may increase, decrease, or alter the effect of another medication. Types of Medication Responses Principles of Pharmacokinetics • As a medication is administered, the body begins removing it. − Duration and effectiveness is determined by: • Dose • Route of administration • Clinical status of the patient Principles of Pharmacokinetics • Pharmacokinetics section of a medication profile states: − Onset: related to absorption and distribution − Peak: related to absorption and distribution − Duration: related to metabolism and elimination Routes of Medication Administration • Absorption − Route of administration must deliver appropriate amount to correct location − Bioavailability: percentage of unchanged medication that reaches systemic circulation • Varies by medication • IV route has 100% bioavailability Routes of Medication Administration • Oral, orogastric tube, and nasogastric tube − Medications are administered into GI tracts − Patient must: • Be conscious • Be able to swallow • Have a nasogastric tube or orogastric tube Routes of Medication Administration • Endotracheal − Not considered a reliable method − If endotracheal medications must be given: • Administer at least 2 to 2.5 times the IV dose. • Follow with a 10- to 15-mL flush with sterile water or normal saline. Routes of Medication Administration • Intranasal − Liquid medications are converted into a mist that is sprayed into one or both nostrils. − Absorption is rapid. − Bioavailability is close to 100%. − No risk for needlestick injury Routes of Medication Administration • Intravenous − Preferred method in the prehospital setting − Catheter is inserted into a peripheral or external jugular vein − Bioavailability is 100%. − Onset is quick. Routes of Medication Administration • Intravenous (cont’d) − Limitations: • Access is difficult in several groups of patients. • Procedure may cause pain or infection and is time consuming. • Certain classes can cause pain and tissue damage. Routes of Medication Administration • Intraosseous − A needle is inserted into the bone. − Can generally be left in place up to 24 hours − Contraindicated in bones that are fractured. Routes of Medication Administration • Intramuscular − Medication is injected into large muscle. − Bioavailability is from 75% to 100%. − Confirm that: • Medication is appropriate for IM use • Particular muscle should be used • Particular technique for injection should be used Routes of Medication Administration • Subcutaneous − Medication is injected into SC tissue site. − Certain medications are indicated for SC use only. − Slower absorption may prevent adverse cardiovascular effects. Routes of Medication Administration • Dermal and transdermal − May alter a patient’s clinical presentation or interfere with other medications administered − Deliver a relatively constant dose of mediation during a long period. − Often contain a large quantity of medication Routes of Medication Administration • Sublingual − Nitroglycerin is often given using this route. − Medication is placed under patient’s tongue. − Bioavailability is low. − Large doses are required. − Patients must be conscious and alert. Routes of Medication Administration • Inhaled or nebulized − Limited to oxygen and antidote − May assist patients with medications via metered-dose inhalers − Medication may be nebulized. • Potential to cause bronchospasm Routes of Medication Administration • Rectal − Preferred over the oral route − Usually not subject to first-pass metabolism − May have greater than 90% bioavailability − Manufactured in suppository form − Absorption can be unpredictable. Routes of Medication Administration • Ophthalmic − Generally limited to ocular anesthetic agents • Other methods of administration − Hemodialysis: blood is pumped through a dialysis machine. − Paramedics should not use any routes they are not trained to use. Distribution of Medication • Determined by: − Chemical properties − Physical properties − Patient factors • System of barriers prevent the introduction of foreign substances into the body. − Medication must move through these barriers. Distribution of Medication • Osmosis is used to enhance the distribution of certain medications. − Allows IV fluids to leave the intravascular space and enter various tissues and cells Distribution of Medication • Filtration − A process within the body that is used to redistribute water and other particles − Hydrostatic pressure forces various fluids against semipermeable membranes. Distribution of Medication • Epithelial cells create a continuous barrier. − Small nonionic and lipophilic molecules pass easily through cell membranes. − Larger hydrophilic and ionic molecules must find another route of entry. • Pinocytosis • Facilitated diffusion • Active transport Distribution of Medication • Medications must also move through capillary walls to reach some tissues. − Three barriers: • Blood-brain barrier • Blood-placenta barrier • Blood-testes barrier Distribution of Medication • Plasma protein binding − Medication molecules temporarily attach to proteins in the blood plasma. − Concentration of medication may change as: • Plasma protein levels change. • Another medication that binds with plasma protein is introduced. Distribution of Medication • Lipophilic medications can be sequestered in the fat tissues of an obese person. − The medication is released slowly, causing prolonged effects. Volume of Distribution • Describes extent to which a medication will spread within the body − Medications with a lower volume of distribution have higher levels present in the plasma. Medication Metabolism • Biotransformation: medication becomes a metabolite − Active metabolites: capable of pharmacologic activity − Inactive metabolites: no longer possess ability to alter a cell process or body function Medication Metabolism • Possible effects of biotransformation: − An inactive substance can become active. − An active medication can be changed into another active medication. − An active medication can be inactivated. − An active medication can be transformed into a substance that is easier to eliminate. Medication Metabolism • Most biotransformation occurs in the liver. − P-450 system: alters the chemical structure of a medication − The kidneys, skin, lungs, GI tract, and other tissues may also cause biotransformation. − Makes medications easier to eliminate Medication Elimination • Primarily removed by the kidneys • Two patterns: − Zero-order elimination: fixed amount of a substance is removed during a certain period − First-order elimination: rate of elimination is influenced by substance’s plasma levels Medication Elimination • Half-life: time needed for metabolism or elimination of 50% of the substance in plasma − Altered by factors such as: • Disease states • Changes in perfusion • Medication interactions Medication Elimination • Medications are administered at a dose and frequency equal to body’s rate of elimination. • Smaller amounts of medication can be eliminated in expired air. Reducing Medication Errors • Medication decisions are often based on memory and frequently occur in the context of a stressful, life-threatening situation. Reducing Medication Errors Reducing Medication Errors • The Institute for Safe Medication Practices (IMSP) has developed a list of error-prone medication abbreviations. − When these are used, there is an decreased likelihood of a medication error. Medications Used in Airway Management • Sedative-hypnotic agents − Etomidate (Amidate): imidazole derivative that works as a single-dose profound sedative • Minimal effect on blood pressure • Begins working in 30–60 seconds • No more than one dose should be given. Medications Used in Airway Management • Sedative-hypnotic agents (cont’d) − Ketamine (Ketalar) • Causes profound dissociation and anesthesia • Can maintain BP and heart rate • Raises intracranial pressure • Causes some degree of bronchodilation Medications Used in Airway Management • Benzodiazepines − Potent, antiseizure, anxiolytic, and sedative properties − High doses are required to achieve adequate sedation. − Pregnancy Class D: potentially harmful to the fetus Medications Used in Airway Management • Chemical paralytic agents − Provide muscle relaxation. − Bind with nicotinic receptor sites. • Antagonizes ACh, which normally causes muscle contractions when released Medications Used in Airway Management Medications Used in Airway Management • Chemical paralytic agents (cont’d) − Succinylcholine (Anectine): depolarizing paralytic agent • Rapid onset and relatively brief duration • Adverse effects include hyperkalemia, bradycardia, an elevated intraocular pressure, and malignant hyperthermia. Medications Used in Airway Management • Chemical paralytic agents (cont’d) − Nondepolarizing paralytic agents • Compete with ACh at nicotinic receptor sites. • Rocuronium (Zemuron): rapid onset; short duration • Vecuronium (Norcuron): long onset; available as a powder for reconstitution Medications Used in Airway Management • Other airway medications − When upper airway edema is present, the following may be used: • Corticosteroid • Vasoconstrictor • Bronchodilator Medications Used in Respiratory Management • Beta-agonist medications − Primary treatment for acute bronchospasm − Cause muscle relaxation and bronchodilation − Selective: target only beta-2 receptor sites − Nonselective: affect beta-1 and beta-2 Medications Used in Respiratory Management • Beta-agonist medications − Albuterol: selective beta-2 agonist • Typically nebulized or administered using an MDI for emergency treatment of bronchospasm − Levalbuterol: similar to albuterol; less beta-1 effects − Terbutaline and epinephrine Medications Used in Respiratory Management • Mucokinetic and bronchodilator medications − Ipratropium bromide (Atrovent): antagonizes muscarinic receptors • Causes bronchodilation and decreased mucous in the upper and lower airways Medications Used in Respiratory Management • Corticosteroids − Administered to reduce airway inflammation and improve oxygenation and ventilation − Have immunosuppressant properties − Many contraindications and adverse effects Medications Affecting the Cardiovascular System • Antidysrhythmic medications − Target cells within the heart to: • Resolve dysrhythmia. • Suppress ectopic foci. − Vaughan-Williams classification groups medications into four classes Medications Affecting the Cardiovascular System • Five phases of cardiac cell activity − Phase 4: Cardiac cells are at rest. − Phase 0: Rapid influx of sodium ions − Phase 1: Sodium decreases; potassium exits. − Phase 2: Calcium moves in; potassium exits. − Phase 3: Calcium movement ceases; continued outflow of potassium. Medications Affecting the Cardiovascular System • Class I: Antidysrhythmic medications − Slow the movement of sodium in cardiac cells − Procainamide: suppresses activity of ectopic foci and slows conduction velocity − Lidocaine: blocks sodium channels • Resolves ventricular dysrhythmias; suppresses ectopic foci Medications Affecting the Cardiovascular System • Class II: Antidysrhythmic medications/ beta-adrenergic blocking agents − Inhibit catecholamine activation of beta receptor sites. − May cause massive conduction abnormalities when given with calcium channel blockers Medications Affecting the Cardiovascular System • Class II: Antidysrhythmic medications/ beta-adrenergic blocking agents (cont’d) − Metoprolol (Lopressor): reduces heart rate during myocardial ischemia and atrial tachycardias Medications Affecting the Cardiovascular System • Class III: Antidysrhythmic medications − Prolong the absolute refractory period. − Treats atrial or ventricular tachycardias − Amiodarone (Cordarone) • Administered by IV route; can be continued orally • May cause adverse cardiovascular effects and lifethreatening pulmonary conditions Medications Affecting the Cardiovascular System • Class IV: Antidysrhythmic medications/ calcium channel blockers − Variety of potential uses − Displace calcium at certain receptor sites or enter smooth muscle cells in place of calcium. − Decrease automaticity of ectopic foci and velocity of cardiac contraction. Medications Affecting the Cardiovascular System • Class IV: Antidysrhythmic medications/ calcium channel blockers (cont’d) − Verapamil (Calan) and diltiazem (Cardizem) • Control heart rate in patients with atrial fibrillation or atrial flutter. • Administered IV over 2 minutes • Require continuous electrocardiographic and frequent blood pressure monitoring. Medications Affecting the Cardiovascular System • Adenosine (unnamed class) − Decreases cardiac conduction velocity and prolongs the effective refractory period • Produces pause in cardiac activity − Rapid onset and brief duration − Administered through large-bore proximal IV Additional Cardiovascular Medications • Alpha-adrenergic receptor antagonists − Prevent endogenous catecholamines from reaching alpha receptors • Lower blood pressure. • Decrease systemic vascular resistance. − Prescribed for patients with hypertension, enlarged prostate, glaucoma Additional Cardiovascular Medications • Alpha-adrenergic receptor antagonists (cont’d) − Clonidine (Catapres): primarily alpha-2 receptor agonist − Phentolamine (Regitine): subcutaneously injected to reverse vasoconstriction in tissue − Labetalol (Trandate): alpha-1, beta-1, and beta-2 antagonism properties Additional Cardiovascular Medications • Angiotensin-converting enzyme inhibitors − Alter function of rennin-angiotensin system • Cause blood pressure and cardiac afterload to decrease. − Patients may: • Have a chronic, dry cough • Experience sudden, life-threatening angioedema Additional Cardiovascular Medications • Anticholinergic medications − Atropine: muscarinic receptor antagonist • Effectiveness is related to its concentration at receptor sites compared with ACh. • Treats bradycardia when vagal stimulation of muscarinic-2 receptors is suspected Additional Cardiovascular Medications • Anticholinergic medications (cont’d) − Atropine (cont’d) • Used before airway management • Life-saving antidote for acetylcholinesterase inhibitor toxicity Additional Cardiovascular Medications • Catecholamines and sympathomimetics − Catecholamines: stimulate receptor sites in the sympathetic nervous system. • Contain catechol group and monoamine oxidase group. • Rapidly metabolized, with a brief duration of action Additional Cardiovascular Medications • Catecholamines and sympathomimetics (cont’d) − Sympathomimetics: synthetic chemicals that mimic catecholamines • Include amphetamines, albuterol, phenylephrine, cocaine • Longer duration than catecholamines Additional Cardiovascular Medications • Epinephrine (Adrenalin): catecholamine that stimulates alpha, beta-1, and beta-2 receptor sites − Can be administered IV, IO, IM, SC, endotracheal, and nebulized − Can dramatically increase cardiac workload and myocardial oxygen demand Additional Cardiovascular Medications • Norepinephrine (Levophed): catecholamine that simulates beta-1 and alpha receptor sites − Administered by continuous IV infusion − Titrated according to patient response − Can cause tissue necrosis if extravasation occurs Additional Cardiovascular Medications • Dopamine (Inotropin): primary medication for hypotension refractory to volume resuscitation • Dobutamine: synthetically manufactured catecholamine that is similar to dopamine − Not routinely initiated in the prehospital setting Additional Cardiovascular Medications • Phenylephrine (Neo-Synephrine): synthetic, almost pure, alpha agonist medications − Potent vasoconstrictor − Longer duration than catecholamines − May cause reflex tachycardia, tachyphylaxis − Extravasation is a major concern. Additional Cardiovascular Medications • Vasopressin (Pitression): potent vasopressor medication − Treats GI bleeding, diabetes insipidus, shock, and cardiac arrest. − Can be administered when other catecholamines are ineffective in treating shock Additional Cardiovascular Medications • Direct vasodilator medications − Used for the management of: • Uncontrolled hypertension • CHF • Myocardial infarction • Cardiac ischemia • Cardiogenic shock Additional Cardiovascular Medications • Direct vasodilator medications (cont’d) − Nitroglycerin (Nitro-Bid, Nitrostat) • Dilates veins and coronary arteries • Physiologic responses: relief of chest pain and decrease in blood pressure • IV doses begin at 5 µg/min in adults (can be increased to 200 µg/min) Additional Cardiovascular Medications • Direct vasodilator medications (cont’d) − Nitroglycerin (Nitro-Bid, Nitrostat) (cont’d) • Prone to causing tolerance • Tablets prone to degradation • Should not be taken if taking phosphodiesterase-5 inhibitors used for erectile dysfunction Additional Cardiovascular Medications • Direct vasodilator medications (cont’d) − Sodium nitroprusside (Nipride) • Potent IV vasodilator affecting the smooth muscle of veins and arteries • IV infusion rates can be adjusted to maintain optimal blood pressure and cardiac output. • Effects decrease rapidly once infusion stops Additional Cardiovascular Medications • Direct vasodilator medications (cont’d) − Hydralazine (Apresoline) • Dilates arterioles, lowering pulmonary and systemic vascular resistance • In emergency, administered over at least 1 minute and repeated up to 20 to 30 minutes Additional Cardiovascular Medications • Diuretic medications − Administered to: • Correct volume overload • Manage CHF • Improve respiration in pulmonary edema patients • Potentially preserve kidney function Additional Cardiovascular Medications • Diuretic medications (cont’d) − Furosemide • Use careful consideration before administering to patients with hemodynamic instability and known electrolyte disturbances. • Administered by IV over 1 to 2 minutes per 40-mg dose Additional Cardiovascular Medications • Diuretic medications (cont’d) − Mannitol • Used to decrease intracranial pressure associated with cerebral edema Blood Product Administration • The average adult has about 5 L of blood. − Constitutes approximate 7% to 8% of body weigh. − Trauma or a medical condition can alter the total amount, composition, or performance of the blood. Blood Product Administration • Blood components are: − Type-specific − Cross-matched − Unmatched • If choice is not clear, contact online medical control or sending physician. Blood Product Administration • Blood products require careful monitoring during administration. − Monitor pulse rate and blood pressure. − Reassess temperature frequently. − If indwelling urinary catheter is present, monitor for changes in urine color. Packed Red Blood Cells • Administered to correct anemia − Rate of administration should be proportional to rate of blood cell loss. Packed Red Blood Cells • Unit contains approximately 225 to 250 mL of concentrated RBCs − Patients at risk for volume overload require slow administration and careful monitoring. • Typically administered over no longer than 4 hours per unit Packed Red Blood Cells • Typically administered over no longer than 4 hours per unit • Units usually contain a citrate-based preservative − Hypocalcemia or hyperkalemia may develop. Fresh Frozen Plasma • Used to treat impaired blood clotting • Must be compatible with blood type − Does not need to be Rh compatible • Units hold 225–250 mL − Require defrosting before administration Fresh Frozen Plasma • Cryoprecipitate − A blood product that contains a concentrated assortment of blood clotting factors • Without the additional volume present in FFP Platelets • Used to correct thrombocytopenia • Must be blood type and Rh compatible Medications that Alter Blood Performance • Blood platelets combine with coagulation chemicals to terminate bleeding. • When clotting occurs, a thrombus is crated. − Medications can alter the ability of the blood to form a thrombus. Medications that Alter Blood Performance • Anticoagulant medications − Impair function of clotting or coagulation chemicals in the bloodstream. − Enhance the function of substances in the blood that inhibit clot formation. − Heparin and enoxaparin (Lovenox) Medications that Alter Blood Performance • Antiplatelet medications − Prevent new thrombus formation or extension of an existing thrombus − Includes: • Aspirin • Clopidogrel (Plavix) and ticlopidine (Ticlid) • Glycoprotein IIb/IIIa inhibitor medications Medications that Alter Blood Performance • Fibrinolytics − Dissolve blood clots in arteries and veins. − Can cause life-threatening hemorrhage − Avoid multiple IV attempts and unnecessary trauma. • Prolonged prehospital time may preclude administration. Medications Used for Neurologic Conditions • Analgesic medications − Stimulate opioid receptors to relieve pain. − Known to cause tolerance, cross-tolerance, and addiction − Can cause profound sedation, respiratory depression, and apnea when excessive doses are administered Medications Used for Neurologic Conditions • Analgesic medications (cont’d) − Morphine sulfate • Known to cause nausea or vomiting in up to 28% of patients − Fentanyl (Sublimaze) • Does not have the same risk of nausea and histamine release Medications Used for Neurologic Conditions • Opiate antagonist medication − Naloxone: reverses the effects of excessive opioid chemicals in the body • Efficacy is dose-dependent. • Only administer enough to correct life-threatening conditions Medications Used for Neurologic Conditions • Opiate antagonist medication (cont’d) − Phenytoin (Dilantin) and fosphenytoin (Cerebyx): prevent seizure activity. • May receive on a long-term basis • Administered by IV infusion • Fosphenytoin has fewer adverse effects than phenytoin. Medications Affecting the GI System • Histamine-2 receptor antagonists − Decrease acid secretion in the stomach. − Prevent histamine from stimulating receptor sites on parietal cells in the stomach. − Includes ranitidine (Zantac), cimetidine (Tagamet), famotidine (Pepcid) Medications Affecting the GI System • Antiemetic medications − Used to treat nausea and vomiting − Promethazine (Phenegran) and prochlorperazine (Compazine) • Can be given orally or via IV • Adverse effects are related to IV administration. Medications Affecting the GI System • Antiemetic medications (cont’d) − Metoclopramide (Reglan): increases GI motility • Available orally, by slow IV injection, and by IV infusion − 5-HT3 receptor antagonists: prevent certain mechanisms that induce vomiting. • Available in oral and IV preparations Medications Affecting the GI System • Octreotide (Sandostatin) − A synthetic version of somatostatin − Decreases secretion of insulin, glucagons, growth hormones, and various other chemicals − Has many potential uses Miscellaneous Medications Used in the Prehospital Setting • Acetaminophen (Tylenol, APAP) − Antipyretic and mild analgesic properties − Available as a tablet, capsule, liquid, and rectal suppository • Oral administration should be avoided in patients with high risk of seizures or airway compromise. − Adverse effects are rare. Miscellaneous Medications Used in the Prehospital Setting • Calcium preparations − Can be used for: • Antidote to calcium channel blocker overdose • Treatment of magnesium (sulfate) toxicity • Prevention of dysrhythmia • Calcium repletion in patients with hypocalcemia • Calcium restoration from hydrofluoric acid • Prevention of hypotension Miscellaneous Medications Used in the Prehospital Setting • Calcium preparations − IV calcium is available as: • Calcium chloride • Calcium gluconate − Monitor IV sites to avoid extravasation. − Avoid SC or IM administration. Miscellaneous Medications Used in the Prehospital Setting • Dextrose − Used for known or presumptive hypoglycemia − Administered through a large IV catheter − Initial dose: 25 g of a 50% dextrose solution for a total volume of 50 mL Miscellaneous Medications Used in the Prehospital Setting • Diphenhydramine − Used for a variety of clinical situations − Competitive histamine-1 receptor antagonist − Typically administered by IV or IM − Adverse effects are generally limited to: • Mild sedation, palpitations, anxiety Miscellaneous Medications Used in the Prehospital Setting • Glucagon − Naturally occurring peptide, manufactured commercially − May be used: • To treat hypoglycemia • To provide increased heart rate and contractility • To treat severe calcium channel blocker overdoses • When a foreign body lodges in the esophagus Miscellaneous Medications Used in the Prehospital Setting • Ketorolac − May be used as an alternative or adjunct to opioid analgesic medications − NSAID that inhibits prostaglandin synthesis − Typically administered via IV or IM − Do not administer to patients susceptible to GI bleeding. Miscellaneous Medications Used in the Prehospital Setting • Magnesium sulfate − IV electrolyte medication • For cardiac arrest: 1 to 2 g given during 1 to 2 minutes • In other situations: during at least 5 minutes − Replaces magnesium deficiencies in the body − Relaxes various smooth muscle tissues Miscellaneous Medications Used in the Prehospital Setting • Sodium bicarbonate − Alkalinizing agent − Administered by rapid IV push or added to IV fluids for intermittent or continuous infusion − Excessive administration can cause: • Fluid volume overload, alkalosis, electrolyte abnormalities, cerebral and pulmonary edema Miscellaneous Medications Used in the Prehospital Setting • Thiamine − Commercial medication preparation of vitamin B1 − Usually administered by the IV route − Toxic and adverse effects are unlikely when therapeutic doses are administered. Summary • Certain medications discovered in ancient times are still in use. • Controlled Substances Act of 1970 − Also known as the Comprehensive Drug Abuse Prevention and Control Act • Schedule I medications may not be used for medical purposes. Summary • Schedule II through V medications require locked storage, significant record keeping, and controlled wasting procedures. • All medications in the United States are given three names: chemical, generic, and brand. Summary • The United States Pharmacopeia-National Formulary and Physicians’ Desk Reference provide details about thousands of medications. • Direct sunlight, extreme temperatures, and physical damage to containers can make medications ineffective or unsafe for use. Summary • Controlled medications require additional security, record keeping, and disposal precautions. • Pharmacodynamics is the action of a medication after it is administered and begins to alter a function or process in the body. Summary • Medications are developed to reach and bind with particular receptor sites of target cells. • Newer medications are designed to target only very specific receptor sites on certain cells in an attempt to minimize side effects. Summary • Many factors determine how a particular medication will affect a patient. • Side effect and adverse effect are often used interchangeably. Adverse effects are undesirably or harmful responses to a medication. Summary • The relationship between the median effective dose and the median lethal dose or median toxic dose is the therapeutic index or therapeutic ratio. • Repeated exposure to a medication within a particular class may cause a tolerance affecting other medications within the same class. Summary • Patients receiving multiple medications are at risk of an unintended interaction between or among the various substances. • As the body moves a medication, it may alter the structure of the medication. Summary • Many medication factors determine which cells a particular medication will reach. • Biotransformation is a process that has four possible effects on a medication absorbed into the body. • Paramedics are at constant risk for cognitive error or technical error. Summary • There are six rights of medication administration. − Right patient − Right medication − − − − Right dose Right route Right time Right documentation and reporting Summary • Medications and medication groups used in the prehospital setting are for: − Airway management − Respiratory management − − − − Cardiovascular system Gastrointestinal system Neurologic system Blood products and medications affecting the blood Credits • Chapter opener: Courtesy of Rhonda Beck • Backgrounds: Orange—© Keith Brofsky/Photodisc/Getty Images; Gold—Jones & Bartlett Learning. Courtesy of MIEMSS; Green— Courtesy of Rhonda Beck; Purple—Jones & Bartlett Learning. Courtesy of MIEMSS. • Unless otherwise indicated, all photographs and illustrations are under copyright of Jones & Bartlett Learning, courtesy of Maryland Institute for Emergency Medical Services Systems, or have been provided by the American Academy of Orthopaedic Surgeons.
