PHARMACEUTICAL AND MEDICINAL CHEMISTRY III

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Learning Outcomes

Explain antibiotics.
Classify antibiotics chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain Sulfonamides.
Classify sulfonamides chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain quinolones.
Classify quinolones chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain oxazolidinones.
Classify oxazolidinones chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain nitroheterocycles.
Classify nitroheterocycles chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain antifungal drugs.
Classify antifungal drugs chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain Antiviral Drugs.
Classify antianginal drugs chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain antimycobacterial drugs.
Classify antimycobacterial drugs chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain antiprotozoal drugs.
Classify antiprotozoal drugs chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain anthelmintic drugs.
Classify anthelmintic drugs chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain the drugs used against ectoparasites.
Name the drugs used against ectoparasites.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain Antiseptics and Disinfectants.
Classify antiseptics and disinfectants chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain Anticancer Drugs.
Classify anticancer drugs chemically.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain antitussive, expectorant and mucolytic drugs.
Classify antitussive drugs according to their chemical structures.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Explain Bronchodilator and Antiasthmatic Drugs.
Explain the chemical structures of plasma substitute compounds.
Classify bronchodilator drugs and other anti-asthmatic drugs according to their chemical structure.
Explains the chemical class in which the active ingredients are contained.
Explains the structure-activity relationships of active ingredients.
Names the active ingredients chemically.
Explains the receptor/enzyme interaction sites of active substances.
Explains the synthesis methods of active substances.
Describes the metabolism pathways and metabolites of active substances.
Be able to perform synthesis applications.
Determine the appropriate method for the synthesis of the target compound.
Explain the reaction conditions of the synthesis.
Explain the reaction equation and mechanism of synthesis.
Explains the properties and purposes of the chemical substances required for synthesis.
Explain the properties and uses of devices required for synthesis.
Synthesizes the target compound.
Be able to perform separation and purification applications.
Applies the appropriate process to remove the synthesis product from the reaction medium.
Explains the physical and chemical properties of the synthesis product.
Calculates the theoretical, practical and percentage yield of the synthesis product.
Crystallizes the synthesis product.
Be able to perform IR Spectroscopy applications.
Lists the estimated IR data of the compounds.
It determines which functional groups the bands in the IR spectrum belong to.
Determine the structure by interpreting IR spectra.
Be able to perform 1H NMR Spectroscopy applications.
Lists the predicted 1H-NMR data of the compounds.
It determines which protons the peaks observed in 1H-NMR spectra belong to.
Determine the structure by interpreting 1H-NMR spectra.
Be able to perform mass spectroscopy applications.
Lists the predicted MS data of the compounds.
It determines which parts the peaks observed in the mass spectrum belong to.
It determines the molecular ion peak in mass spectra.
It determines the main peak in mass spectra.
Interpret the mass spectra of compounds.