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Graduate Degree
Pharmaceutical Chemistry (MS) ()
METABOLISM, METABOLITES AND ROLE IN DRUG DESIGN
Course Information

Course Information

Course Information

Course Title	Code	Semester	L+U Hour	Credits	ECTS
METABOLISM, METABOLITES AND ROLE IN DRUG DESIGN	34104065		0 + 0	3.0	3.0

Prerequisites

None

Language of Instruction	Turkish
Course Level	Graduate Degree
Course Type	Compulsory
Mode of delivery
Course Coordinator
Instructors
Assistants
Goals	Metabolites which occurs once taken into the body and new drug design starting from these
Course Content	Introduction to drug metabolism, Factors that effect metabolism, Metabolism pathways, Phase I reactions, Aromatic hydroxylation and its examples, Hydoxylation of benzylic molecules and its examples, Oxidation in aliphatic reactions and its examples, Epoxidation and its examples, N/O/S-dealkylation and their examples, N/S-oxidation and their examples, Dehalogenation and examples, Reduction and hydrolysis reactions and examples, Drug design according to metabolites
Learning Outcomes	1) Knows absorption, distribution and excretion characteristics of drug active substance in the body, gains information about drug development based on from possible metabolites and relationships between chemical structure and biotransformation. 2) The design, synthesis and analysis of pharmaceutical active ingredients, and evaluate the facts of their behavior in biological environment and possible solutions. 3) Applies studies on design, synthesis, structure elucidation and analysis of pharmaceutically active substances.

Weekly Topics (Content)

Week	Topics	Teaching and Learning Methods and Techniques	Study Materials
	Epoxidation and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
	Dehalogenation and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
1. Week	Introduction to drug metabolism (biotransformation)	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
2. Week	Factors affecting metabolism	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
3. Week	Metabolic pathways	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
4. Week	Phase I reactions	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
5. Week	Aromatic hydroxylation and examples	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
6. Week	Benzylic hydroxylation and examples	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
7. Week	Oxidation of aliphatic molecules and examples	Lecture Colloquium Problem Based Learning	Presentation (Including Preparation Time)
8. Week	Epoxidation and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
9. Week	N, O, S-dealkylation and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
10. Week	N, S-oxidation and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
11. Week	Dehalogenation and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
12. Week	Reduction, hydrolysis reaction, and examples	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
13. Week	New drug design according to the occurring metabolites	Lecture; Question Answer Colloquium Problem Based Learning	Presentation (Including Preparation Time)
14. Week	Final exam

Sources Used in This Course

Recommended Sources

Introduction to Drug Metabolism, Dr G Gordon Gibson, Paul Skett, Cengage Learning; 3Rev Ed edition, 2001.

Relations with Education Attainment Program Course Competencies

Program Requirements	Contribution Level	DK1	DK2	DK3
PY1	3	0	0	0
PY2	3	0	0	0
PY3	3	0	0	0

*DK = Course's Contrubution.

	0	1	2	3	4	5
Level of contribution	None	Very Low	Low	Fair	High	Very High

.

ECTS credits and course workload

Event	Quantity	Duration (Hour)	Total Workload (Hour)
Course Duration (Total weeks*Hours per week)	14	3	42
Work Hour outside Classroom (Preparation, strengthening)	14	1	14
Homework	7	1	7
Presentation (Including Preparation Time)	10	1	10
Activity (Web Search, Library Work, Trip, Observation, Interview etc.)	6	1	6
Final Exam	1	1	1
Total Workload
Total Workload / 30 (s)
ECTS Credit of the Course			30

Quick Access

Pharmaceutical Chemistry (MS)
With Thesis

Course Information

Course Information
Weekly Topics (Content)
Sources Used in This Course
Relations with Education Attainment Program Course Competencies
ECTS credits and course workload