Introduction to Health and Medical Physics
A.Y. 2019/2020
Learning objectives
Acquire basic concepts of NMR, MRI (T1, T2, spectra, k-space, sequences). Images through Fourier Transform and Radon Transform.
Acquire the fundamental concepts of radiotherapy with photons and charged particles together with the knowledge of the basic aspects of radiobiology.
Acquire le basic concepts of medical imaging, production and detection of RX, interaction of RX with matter, the dosimetric indices and basic concepts of ultrasound imaging.
Acquire the fundamental concepts of radiotherapy with photons and charged particles together with the knowledge of the basic aspects of radiobiology.
Acquire le basic concepts of medical imaging, production and detection of RX, interaction of RX with matter, the dosimetric indices and basic concepts of ultrasound imaging.
Expected learning outcomes
At the end of the course the student will have acquired the knowledge concerning:
- The interaction of ionizing radiation (photons and charged particles) with matter;
- The bases of dosimetry;
- The fundamental concepts of radiotherapy with photons and charged particles;
- Basic aspects of radiobiology;
- The accelerators for hadrontherapy
- Basic concepts of the development of a hadrontherapy treatment plan
- Basic aspects of medical imaging;
- Production and detection of X-rays;
- Conventional Radiology
- Mammography and Computed Tomography
- The basic concepts of MR imaging (T1, T2, Spectroscopy, k-space. Sequences)
- The interaction of ionizing radiation (photons and charged particles) with matter;
- The bases of dosimetry;
- The fundamental concepts of radiotherapy with photons and charged particles;
- Basic aspects of radiobiology;
- The accelerators for hadrontherapy
- Basic concepts of the development of a hadrontherapy treatment plan
- Basic aspects of medical imaging;
- Production and detection of X-rays;
- Conventional Radiology
- Mammography and Computed Tomography
- The basic concepts of MR imaging (T1, T2, Spectroscopy, k-space. Sequences)
Lesson period: Second semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Lesson period
Second semester
Course syllabus
The teaching program covers the following points:
- The interaction of ionizing radiation (photons and charged particles) with matter;
- The bases of dosimetry;
- The fundamental concepts of radiotherapy with photons and charged particles;
- Basic aspects of radiobiology;
- The accelerators for hadrontherapy
- Basic concepts of the development of a hadrontherapy treatment plan
- Basic aspects of medical imaging;
- Production and detection of X-rays;
- Conventional Radiology
- Mammography and Computed Tomography
- The basic concepts of MR imaging (T1, T2, Spectroscopy, k-space. Sequences)
- The interaction of ionizing radiation (photons and charged particles) with matter;
- The bases of dosimetry;
- The fundamental concepts of radiotherapy with photons and charged particles;
- Basic aspects of radiobiology;
- The accelerators for hadrontherapy
- Basic concepts of the development of a hadrontherapy treatment plan
- Basic aspects of medical imaging;
- Production and detection of X-rays;
- Conventional Radiology
- Mammography and Computed Tomography
- The basic concepts of MR imaging (T1, T2, Spectroscopy, k-space. Sequences)
Prerequisites for admission
Basis of electromagnetism, nuclear physics and structure of matter
Teaching methods
The teaching method consists of lectures in the classroom, during which the topics of the program are explained together with examples and exercises
Teaching Resources
Slides and bibliographic documents available or suggested on the website of the course in ARIEL (http://ariel.unimi.it/)
Assessment methods and Criteria
The assessment method consists of an oral test aimed at verifying the knowledge acquired by the student and the related processing skills and critical reasoning on the study carried out
FIS/07 - APPLIED PHYSICS - University credits: 6
Lessons: 42 hours
Shifts:
Professor(s)