PPT NO. 2 - Introduction to Medicinal Chemistry PDF

Summary

This document provides an introduction to medicinal chemistry, covering topics such as the significance of medicinal chemistry, pharmacophores, solubility, and drug interaction. The document is organized as a question and answer format, which makes it useful for learning the topics by answering the introductory questions.

Full Transcript

INTRODUCTION TO MEDICINAL CHEMISTRY
PPT NO. 2 (DR. GUPTA)

1. What is the significance of medicinal chemistry in pharmacy education?

A: It helps understand the structure, interactions, and properties of drugs.

2. What can a medicinal chemist determine for a drug molecule?

A: Functional groups, interactions with biological targets, acid/base character, polarity, and
solubility.

3. What does SAR stand for in medicinal chemistry?

A: Structure-Activity Relationship.

4. What is a pharmacophore?

A: Essential structural features of a drug responsible for biological activity.

5. How does solubility relate to drug action?

A: Solubility affects drug absorption, distribution, and bioavailability.

6. Name two disciplines that medicinal chemistry combines.

A: Biology and pharmaceutical sciences.

7. What are the ADME properties in drug development?
A: Absorption, Distribution, Metabolism, and Excretion.

8. How does the polarity of a drug affect its solubility?
A: Polar drugs are water-soluble; non-polar drugs are lipid-soluble.
9. What is the partition coefficient (logP) used for?

A: To measure the polarity of a drug between water and lipid environments.

10. What is the role of hydrogen bonding in drug-receptor interactions?
A: It stabilizes the interaction between the drug and receptor.

11. Why must a drug balance hydrophilicity and lipophilicity?

A: To cross biological membranes while remaining soluble in bodily fluids.

12. What types of functional groups increase water solubility?

A: Polar and ionizable groups like hydroxyl and amine groups.

13. What is the effect of alkyl chains on drug solubility?

A: They increase lipophilicity and decrease water solubility.

14. What is the purpose of studying the acidity and basicity of drugs?

A: To predict solubility and ionization in different pH environments.

15. Which functional group is basic: amine or carboxylic acid?
A: Amine.

16. How does the Henderson-Hasselbalch equation relate to drug ionization?

A: It calculates the ionization state of drugs at different pH values.

17. What does a high logP indicate about a drug’s solubility?

A: It is more lipophilic and less water-soluble.
18. What is the main goal of drug design in medicinal chemistry?

A: To achieve the desired therapeutic effect with minimal side effects.

19. What are common acidic functional groups in drugs?
A: Carboxylic acids and phenols.

20. What role do Van der Waals forces play in drug binding?

A: They help drugs fit within receptor binding sites.

21. Define an amphoteric compound.

A: A compound with both acidic and basic functional groups.

22. Why is understanding drug reactivity important?

A: It influences the drug’s stability and potential interactions.

23. What does SAR study in drug molecules?

A: The relationship between chemical structure and biological activity.

24. Why are functional groups critical in drug design?
A: They determine a drug’s solubility, reactivity, and binding interactions.

25. What is a prodrug?

A: A compound that requires activation within the body to become pharmacologically active.

26. Give an example of a prodrug.

A: Atorvastatin.
27. How does drug ionization affect absorption?

A: Ionized drugs are less permeable across lipid membranes.

28. What is the significance of ADME in pharmacokinetics?
A: It determines how the drug is processed in the body.

29. What is the primary functional group in morphine’s pharmacophore?

A: An aromatic ring with a protonated amine and hydrophobic region.

30. How do lipophilic drugs interact with membranes?

A: They diffuse through lipid bilayers more readily.

31. Why are hydroxyl groups important for solubility?

A: They enhance water solubility due to hydrogen bonding.

32. What does a low logP value suggest?

A: The drug is more hydrophilic and water-soluble.

33. What is an example of a nonpolar functional group?
A: Alkyl chains.

34. What does drug polarity impact besides solubility?

A: Membrane permeability and distribution.

35. What is the pharmacophore of statins?

A: The structure responsible for inhibiting cholesterol synthesis.
36. What is the difference between organic and medicinal chemistry?

A: Organic chemistry studies molecules; medicinal chemistry focuses on their therapeutic uses.

37. How do functional groups like nitro groups affect logP?
A: They decrease logP, increasing hydrophilicity.

38. What are macromolecular drug targets?

A: Receptors, enzymes, and DNA/RNA.

39. Define “efficacy” in medicinal chemistry.

A: The ability of a drug to produce the desired therapeutic effect.

40. What happens to drug solubility as acidity increases?

A: Solubility in water increases for acidic drugs.

41. Why do drugs with balanced solubility have an advantage?

A: They can move through both aqueous and lipid environments effectively.

42. What is a hydrophobic region’s role in a pharmacophore?
A: It enhances binding with lipophilic regions of receptors.

43. How does polarity affect drug distribution?

A: Polar drugs remain in aqueous compartments, while nonpolar drugs enter lipid tissues.

44. Why is SAR important in drug design?

A: It helps optimize drug efficacy and reduce side effects.
45. What is the function of hydrogen bonds in drug action?

A: They stabilize drug-receptor interactions.

46. Define “bioavailability” in pharmacology.
A: The extent and rate at which a drug reaches systemic circulation.

47. What is a hydrophilic drug characteristic?

A: It dissolves easily in water and circulates in bodily fluids.

48. How does a drug’s structure affect its metabolism?

A: Functional groups can alter enzyme interactions and breakdown rates.

49. What does ionization depend on?

A: The drug’s pKa and the pH of the environment.

50. Why are quaternary ammonium compounds neutral at physiological pH?

A: They do not ionize in water.

51. Why do lipophilic drugs have higher logP values?
A: They have a greater affinity for lipid over aqueous phases.

52. What type of bonding is common in drug-receptor interactions?

A: Ionic, hydrogen, covalent, and Van der Waals interactions.

53. Why is polarity crucial for drug transport?

A: Nonpolar drugs cross membranes more easily than polar ones.
54. What is the impact of adding polar groups to a molecule?

A: It increases hydrophilicity and decreases lipophilicity.

55. What does an aromatic ring contribute to a drug?
A: It provides stability and a hydrophobic region for binding.

56. How does lipophilicity relate to drug toxicity?

A: Highly lipophilic drugs may accumulate in lipid tissues, increasing toxicity risk.

57. What is the advantage of a drug being amphoteric?

A: It can exist in both acidic and basic forms, adjusting to pH changes.

58. What is the significance of functional group chemistry?

A: It determines solubility, reactivity, and pharmacological interactions.

59. How does pH affect weak acid and base drugs?

A: Changes in pH alter their ionization and, consequently, their solubility and absorption.

60. What are the therapeutic implications of a drug's solubility?
A: Solubility affects how a drug is formulated, administered, and absorbed.

61. Why is chemical bonding essential for drug-receptor fit?

A: It enables drugs to bind specifically and tightly to their targets.

62. What effect does adding alkyl groups have on a drug molecule?

A: It increases lipophilicity, making it more likely to bind to lipids.
63. How can SAR studies guide drug modification?

A: They show how changes in structure impact drug activity.

64. What are the primary types of functional groups in drugs?
A: Alcohols, amines, carboxylic acids, and esters.

65. What is the role of the aromatic ring in morphine?

A: It is part of its pharmacophore, essential for receptor binding.

66. Define “bioisosteres” in medicinal chemistry.

A: Groups or atoms with similar properties used to modify drugs while retaining activity.

67. How do enzymes affect drug metabolism?

A: They break down drugs, affecting duration and potency.

68. What is the role of hydrophilic groups in drug design?

A: They improve solubility and distribution in water-based fluids.

69. Why do we study acid-base properties in drug formulation?
A: They influence the drug’s solubility, stability, and absorption.

70. What does the term “protonated amine” refer to in pharmacophores?

A: An amine group with an added hydrogen ion, aiding in receptor binding.

71. How do functional groups affect the logP value?

A: Polar groups decrease logP, making the drug more hydrophilic.
72. Why are covalent bonds uncommon in drug-receptor interactions?

A: They are often too strong and irreversible, limiting drug use.

73. What does “hydrophilic-lipophilic balance” mean in drug design?
A: It is the right mix of water and lipid solubility for optimal drug action.

74. How does ionization state affect drug bioavailability?

A: Un-ionized drugs are absorbed better through membranes.

75. What effect does an ester functional group have on a drug?

A: It can improve lipophilicity and membrane permeability.

76. How does a high logP value affect oral bioavailability?

A: It may reduce solubility and thus limit absorption in the GI tract.

77. What does a functional group’s presence indicate about solubility?

A: Polar groups suggest higher solubility in water.

78. How does pH-dependent ionization influence drug excretion?
A: Ionized drugs are less likely to be reabsorbed, increasing excretion.

79. What is the pharmacophore of a drug?

A: Structural features essential for biological activity.

80. What does “hydrophobic” mean?

A: Water-repelling, often associated with lipid solubility.
81. How does drug solubility affect its route of administration?

A: Soluble drugs are easier to formulate for oral or injectable use.

82. What is the role of basic functional groups in drug absorption?
A: They interact with acidic environments for enhanced absorption.

83. Why is understanding polarity crucial for drug development?

A: It affects solubility, distribution, and receptor binding.

84. How do aromatic amines influence drug structure?

A: They add both hydrophobicity and potential for ionization.

85. Why are lipophilic drugs effective in crossing membranes?

A: They can dissolve in the lipid bilayer.

86. How does the physicochemical property of a drug impact its ADME profile?

A: It influences absorption, distribution, metabolism, and excretion.

87. What does an “acidic drug” mean?
A: A drug with a functional group that donates protons in solution.

88. What is the relationship between drug structure and receptor interaction?

A: Structure dictates affinity and effectiveness of the interaction.

89. How does solubility affect drug onset and duration?

A: Soluble drugs act faster but may have shorter durations.
90. Why are bioisosteric modifications used in drug design?

A: To alter drug properties without losing activity.

91. How does polarity affect the drug’s pharmacokinetic properties?
A: Nonpolar drugs may distribute more in lipid-rich areas.

92. What is the benefit of a balanced solubility in drugs?

A: It supports absorption in aqueous and lipid environments.

93. How does a drug’s molecular size affect its absorption?

A: Smaller molecules diffuse more easily across membranes.

94. What is an example of a highly polar functional group?

A: Hydroxyl group (-OH).

95. Why is lipophilicity important in drugs for brain penetration?

A: Lipophilic drugs cross the blood-brain barrier more effectively.

96. How do electron-donating groups affect acidity?
A: They decrease acidity by stabilizing the molecule.

97. What is the function of an ether group in a drug?

A: It can increase lipid solubility without adding polarity.

98. How do alkanes affect a molecule’s overall logP?

A: They increase logP, enhancing lipophilicity.
99. Why is water solubility essential for intravenous drugs?

A: It ensures they can be dissolved and administered in solution.

100. How does the presence of nitrogen affect drug structure?
A: It can introduce basicity and improve binding with acidic targets.