Öğrencilere foton ve elektron dozimetrisi, tedavi planlaması, doz hesaplamaları, brakiterapi ve radyasyondan korunma fiziği ve tedavi amaçlı radyasyon dağıtımında kalite güvencesinin mantığı hakkında bilgi vermek. Kalite kontrol yöntemlerinin uygulanması tartışmak.
Course Content
This course contains; External beam Radiotherapy,Acquisition of external beam data,Treatment planning principles,Multifield radiation therapy, IMRT, VMAT,Image fusion, registration, segmentation, quantitation,Motion management,Performance testing and equipment QA,Brachytherapy,Brachytherapy sources,Brachytherapy delivery devices,Brachytherapy treatment planning principles,Performance testing and equipment QA in brachytherapy,Special techniques in radiotherapy,Radiation therapy with neutrons, protons, light ions.
Dersin Öğrenme Kazanımları
Teaching Methods
Assessment Methods
PDD, TAR, TMR, TPR vb. gibi dozimetrik parametreleri tanımlar ve tartışır.
10, 6, 9
A
Çeşitli doz ve MU hesaplamalarını tartışmak, analiz eder ve gerçekleştirir.
10, 6, 9
A
Foton dozimetrisinin fiziğinin çeşitli yönlerini tartışır.
10, 17, 6, 9
A
Elektron dozimetrisinin fiziğinin çeşitli yönlerini tartışır.
10, 17, 6, 9
A
Simülasyon ve tedavi planlamasının ilkelerini ve sürecini tartışır.
10, 6, 9
A
Tedavi planlama tekniklerindeki ilerlemeleri tartışır.
10, 6, 9
A
Brakiterapinin mantığını radyoaktif malzemeler, aplikatörler, implant türleri, dozimetri ve güvenlik açılarından tartışır.
10, 6, 9
A
IMRT, SRS, Proton ve TBI gibi özel tedavi prosedürlerinin ilkelerini tartışır.
Performance testing and equipment QA in brachytherapy
Mebis Lecture Notes
13
Special techniques in radiotherapy
Mebis Lecture Notes
14
Radiation therapy with neutrons, protons, light ions
Mebis Lectures
Resources
Radiation Oncology Physics: A Handbook for Teachers and Students
E.B. Podgorsak Technical Editor
Course Contribution to Program Qualifications
Course Contribution to Program Qualifications
No
Program Qualification
Contribution Level
1
2
3
4
5
1
Has the essential knowledge about the structure and functioning of the radiation emitting machines used in radiation oncology, nuclear medicine and radiology.
X
2
Able to follow and implement daily, weekly and monthly quality control programs of radiation emitting machines.
X
3
Able to do the acceptance and commissioning of new machines.
X
4
Able to the treatment planning of patients.
X
5
Able to be a radiation safety officer of the institute.
X
6
Able to participate fields research teams; individually undertake the responsibility of the work assigned and perform it independently.
X
7
Able to evaluate all new information regarding the field and associate them based on available knowledge.
X
8
Uses the communication and computer technology effectively in theoretical and practical studies.
X
9
Able to present theoretical or research data orally or written.
X
10
Adheres to ethical values and behaves according to dynamics of social responsibility.
X
11
Able to do the planning of clinical implementation without giving harm to staff and patient.
X
Assessment Methods
Contribution Level
Absolute Evaluation
Rate of Midterm Exam to Success
50
Rate of Final Exam to Success
50
Total
100
ECTS / Workload Table
Activities
Number of
Duration(Hour)
Total Workload(Hour)
Course Hours
14
8
112
Guided Problem Solving
10
8
80
Resolution of Homework Problems and Submission as a Report
3
30
90
Term Project
0
0
0
Presentation of Project / Seminar
0
0
0
Quiz
2
40
80
Midterm Exam
1
60
60
General Exam
1
60
60
Performance Task, Maintenance Plan
0
0
0
Total Workload(Hour)
482
Dersin AKTS Kredisi = Toplam İş Yükü (Saat)/30*=(482/30)
16
ECTS of the course: 30 hours of work is counted as 1 ECTS credit.
Detail Informations of the Course
Course Description
Course
Code
Semester
T+P (Hour)
Credit
ECTS
PHOTON ELECTRON DOSIMETRY
-
Spring Semester
4+4
6
16
Course Program
Prerequisites Courses
Recommended Elective Courses
Language of Course
Turkish
Course Level
Second Cycle (Master's Degree)
Course Type
Required
Course Coordinator
Assist.Prof. Mustafa ÇAĞLAR
Name of Lecturer(s)
Assistant(s)
Aim
Öğrencilere foton ve elektron dozimetrisi, tedavi planlaması, doz hesaplamaları, brakiterapi ve radyasyondan korunma fiziği ve tedavi amaçlı radyasyon dağıtımında kalite güvencesinin mantığı hakkında bilgi vermek. Kalite kontrol yöntemlerinin uygulanması tartışmak.
Course Content
This course contains; External beam Radiotherapy,Acquisition of external beam data,Treatment planning principles,Multifield radiation therapy, IMRT, VMAT,Image fusion, registration, segmentation, quantitation,Motion management,Performance testing and equipment QA,Brachytherapy,Brachytherapy sources,Brachytherapy delivery devices,Brachytherapy treatment planning principles,Performance testing and equipment QA in brachytherapy,Special techniques in radiotherapy,Radiation therapy with neutrons, protons, light ions.
Dersin Öğrenme Kazanımları
Teaching Methods
Assessment Methods
PDD, TAR, TMR, TPR vb. gibi dozimetrik parametreleri tanımlar ve tartışır.
10, 6, 9
A
Çeşitli doz ve MU hesaplamalarını tartışmak, analiz eder ve gerçekleştirir.
10, 6, 9
A
Foton dozimetrisinin fiziğinin çeşitli yönlerini tartışır.
10, 17, 6, 9
A
Elektron dozimetrisinin fiziğinin çeşitli yönlerini tartışır.
10, 17, 6, 9
A
Simülasyon ve tedavi planlamasının ilkelerini ve sürecini tartışır.
10, 6, 9
A
Tedavi planlama tekniklerindeki ilerlemeleri tartışır.
10, 6, 9
A
Brakiterapinin mantığını radyoaktif malzemeler, aplikatörler, implant türleri, dozimetri ve güvenlik açılarından tartışır.
10, 6, 9
A
IMRT, SRS, Proton ve TBI gibi özel tedavi prosedürlerinin ilkelerini tartışır.
Performance testing and equipment QA in brachytherapy
Mebis Lecture Notes
13
Special techniques in radiotherapy
Mebis Lecture Notes
14
Radiation therapy with neutrons, protons, light ions
Mebis Lectures
Resources
Radiation Oncology Physics: A Handbook for Teachers and Students
E.B. Podgorsak Technical Editor
Course Contribution to Program Qualifications
Course Contribution to Program Qualifications
No
Program Qualification
Contribution Level
1
2
3
4
5
1
Has the essential knowledge about the structure and functioning of the radiation emitting machines used in radiation oncology, nuclear medicine and radiology.
X
2
Able to follow and implement daily, weekly and monthly quality control programs of radiation emitting machines.
X
3
Able to do the acceptance and commissioning of new machines.
X
4
Able to the treatment planning of patients.
X
5
Able to be a radiation safety officer of the institute.
X
6
Able to participate fields research teams; individually undertake the responsibility of the work assigned and perform it independently.
X
7
Able to evaluate all new information regarding the field and associate them based on available knowledge.
X
8
Uses the communication and computer technology effectively in theoretical and practical studies.
X
9
Able to present theoretical or research data orally or written.
X
10
Adheres to ethical values and behaves according to dynamics of social responsibility.
X
11
Able to do the planning of clinical implementation without giving harm to staff and patient.
