Course Information

Course Title	Code	Semester	L+U Hour	Credits	ECTS
DRUG DESIGN METHODS	34183017		0 + 0	3.0	3.0

Prerequisites

None

Language of Instruction	English
Course Level	Graduate Degree
Course Type	Compulsory
Mode of delivery
Course Coordinator
Instructors
Assistants
Goals	Gains information about designing methods of drug active compounds.
Course Content	Studies on investigation and development of active compounds, relationships of effector and target, QSAR, physicochemical parameterization, Hansch analysis methods, Bilinear analysis methods, Free-Wilson modified analysis methods, Relationships between FujitaBan and Hansch models, Applications about models
Learning Outcomes	1) In development studies of drug active compounds, gains basic information about medicinal chemistry and drug design methods. 2) Practise drug design, synthesis, structure elucidation and analyses studies. 3) Gains information about designing methods of drug active compounds.

Weekly Topics (Content)

Week	Topics	Teaching and Learning Methods and Techniques	Study Materials
1. Week	Research and development studies for drug active compounds	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
2. Week	Effector-target relationship	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
3. Week	Quantitative Structure Activity Relationships	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
4. Week	Physicochemical parametrization	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
5. Week	Physicochemical parametrization	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
6. Week	Hansch Analysis Method	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
7. Week	Bilineer Analyses Method	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
8. Week	Free-Wilson Analysis Method	Lecture; Question Answer; Problem Solving Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
9. Week	Relationships between FujitaBan and Hansch Model	Lecture; Question Answer Colloquium Problem Based Learning	Homework Presentation (Including Preparation Time) Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
10. Week	Practises of models	Question Answer; Discussion Colloquium Problem Based Learning	Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
11. Week	Practises of models	Question Answer; Discussion Colloquium Problem Based Learning	Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
12. Week	Practises of models	Question Answer; Discussion Colloquium Problem Based Learning	Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
13. Week	Practises of models	Question Answer; Discussion Colloquium Problem Based Learning	Activity (Web Search, Library Work, Trip, Observation, Interview etc.)
14. Week	Final exam	Question Answer Colloquium Problem Based Learning	Practice (Teaching Practice, Music/Musical Instrument Practice, Statistics, Laboratory, Field Work, Clinic and Polyclinic Practice)

Sources Used in This Course

Recommended Sources

3D Qsar in Drug Design: Recent Advances, Gerd Folkers, 1998 Kluwer Academic Publishers

3D Qsar in Drug Design: Theory Methods and Applications, Hugo Kubinyi, 1993 Kluwer Academic Publishers

Evolutiory Algorithms in Molecular Design, Clark, D.E. (ED), Wiley-VCH, Weinheim, 2000.

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	5	1	5
Presentation (Including Preparation Time)	5	5	25
Report (Including Preparation and presentation Time)	5	1	5
Activity (Web Search, Library Work, Trip, Observation, Interview etc.)	14	1	14
Total Workload
Total Workload / 30 (s)
ECTS Credit of the Course			30

Quick Access

Pharmaceutical Chemistry (MS)
With Thesis (English)

Course Information

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

Course Information

Course Information

Weekly Topics (Content)

Sources Used in This Course

Relations with Education Attainment Program Course Competencies

ECTS credits and course workload

Quick Access

Pharmaceutical Chemistry (MS) With Thesis (English)

Course Information

Pharmaceutical Chemistry (MS)
With Thesis (English)