| | this course includes: Radiation sources, interactions and energy deposition by ionizing radiation in matter; concepts, quantities and units in radiation physics. Isotopes production, measurement of activity, standards, spectrometry, measurement techniques and detectors. Precision, errors, detection limits. Radioanalytical methods, principles and methods of radiation dosimetry. Radiation dosimtery fundamentals, radiation detection instrumentation. | MSc level | | | this course includes: Shielding techniques and facility design, acceptance testing, commissioning, and quality assurance testing on linear accelerators. | MSc level | | | this course includes: Ionizing radiation use in radiation therapy to cause controlled biological effects in cancer patients. Physics of the interaction of the various radiation modalities with body-equivalent materials, and physical aspects of clinical applications. External beam instrumentations and applied dosimetry. Treatment planning: (i) Single beam: direct patient dose calculation, alteration of isodose curves by contour shape, bolus and compenstation filters, dose at exit surface, dose corrections for tissue inhomogeneities, integral does and energy imparted, whole body irradiation (ii) Combination of beams: opposing pairs of beams, combinations of opposing pairs, angled field and wedged pairs, three-field techniques, beam direction, special field, use of CT in treatment planning. Rotating therapy. Treatment planning and recording. | MSc level | | | this course includes:
Techniques deal with specific problems that usually require equipment modifications, special quality assurance procedures and heavy involvement and support from clinical physicists. These include Stereotactic irradiation; Total body irradiation (TBI) with photon beams; Total skin electron irradiation (TSEI); Intraoperative radiotherapy (IORT); Endorectal irradiation; Conformal radiotherapy and intensity modulated radiotherapy (IMRT); Image guided radiotherapy (IGRT); Respiratory gated radiotherapy.
Radiation therapy with neutrons, protons, and heavy ions; Fast neutrons, a form of high-LET radiation, a reduction in the difference in radiosensitivity related to the position of the cells in the mitotic cycle, repair and clinical relevance of the different repair mechanisms. heavy ions and the advantage of better physical selectivity of protons with the radiobiological advantages of fast neutrons for some tumour types.
| MSc level | | | this course includes:
The laboratory course gives some experience in practical aspects of medical physics as applied to radiation therapy. The course complements the theoretical introduction of both the radiation physics and applied dosimetry courses through 12 sessions in the radiation lab. The student is exposed to the operation of various therapy units and dose measuring devices, and to the techniques for measurement of different physical parameters which characterize radiation beams used in radiation therapy.
| MSc level | | | this course includes:
Anatomical nomenclature, bones, thorax, abdomen, endocrine system, respiratory system, digestive system, urinary system, reproductive system, circulatory system, pathology. Homeostasis; general aspects. Blood and body fluid; formation, function and fate.
| MSc level | | | this course includes: Atomic and nuclear structure. Radiatio sources (natural and man-made radiation sources). Radioactivity and radiation. Interaction of radiation with matter, radiation units and limits (basic radiation and physical units). Radiation detection and measurement (detectors - properties of good detectors, such as resolution, volume, efficiency and materials. selecting a detector. different detection instrument such as film badge, TLDs, ionization detectors, scintillation and semiconductor detectors). Radiation protection - principles, shielding, ALARA and radiation protection instruments. Radiation hazards and dosimetry. Biological effects of rdaiation - radiation biophysics, chemistry, damage to proteins and cells. Application of radiation in medicine and engineering - radiatio diagnostic and therapeutic medicine and industrial research | UG level 2012-2013 | | | this course includes: the nature and magnitude of hazards to patients and various health-care settings, techniques to analyze the risks and to address the problems in order to reduce errors and create a safe patient-care environment, probabilistic risk assessment methods, failure mode and effects analysis, human factors analysis and error classification systems, and quality management. Discussion of patient safety standards, recommendations for agencies, and continual quality imrovement, alond with analytical of actual radiation accidents. | MSc level | | | this course include: Motion in One Dimension, Vectors, Motion in Two Dimension, The Laws of Motion, Circular Motion and Other Applications of Newton's Laws, Conservation of Energy, Linear Momentum and Collisions, Rotation of a Rigid Object about a Fixed Axis, Angular Momentum, Static Equilibrium and Elasticity, Universal Gravitation, Fluid Mechanics, and Oscillatory Motion. | UG level | | | درست هذه المادة باللغة العربية كمتطلب جامعة لتخصصات بكالوروس مختلفة في الجامعة و تتناول دراسة التأثيرات المجتمعية على العلم و التكنولوجيا, و فلسفة المعرفة, و تاريخ العلوم عند كل من الاغريق و الرومان و المسلمين و الاوروبيين في العصور الوسطى. | UG | | | Graduation project is prepared in fields of medical physics for example, calibration, quality assurance, quality control for one of the major equipment at the research lab or at the hospital experience. | MSc level |  | | This course is dedicated to familiarise students with the following topics:
Traditional energy sources including: Oil, coal and gas, world reserves of traditional energy resources, advantages/disadvantages of traditional energy use and global warming: effect of industrial pollution on the environment
Renewable energy sources including: solar energy, wind energy, other sources of renewable energy, advantages/disadvantages compared to the traditional energy sources
Nuclear energy including: methods of nuclear energy production, Advantages/disadvantages of using nuclear energy, effect on the environment, nuclear safety, nuclear security
Management of energy sources and resources
| UG | | |
This course includes: effects of ionizing radiation on biological material from molecular interactions, through sub-cellular and cellular levels of organization, to the response of tissues, organs and the whole body. Includes the application of radiation biology in oncology and the biological aspects of environmental radiation exposure. Dose limits and ALARA. Assessment of personal dose and dose commitment. Protection of patients.
| MSc level | | | This course covers different topics including: molecular structure interactions and the mechanisms of chemical reactions. Biochemistry; enzymes, substrates, controll of metabolism. Structure of proteins, carbohydrates and lipids | MSc level | | | this course includes: Techniques deal with specific problems that usually require equipment modifications, special quality assurance procedures and heavy involvement and support from clinical physicists. These include Stereotactic irradiation; Total body irradiation (TBI) with photon beams; Total skin electron irradiation (TSEI); Intraoperative radiotherapy (IORT); Endorectal irradiation; Conformal radiotherapy and intensity modulated radiotherapy (IMRT); Image guided radiotherapy (IGRT); Respiratory gated radiotherapy. Brachytherapy
Radiation therapy with neutrons, protons and heavy ions; Fast neutrons, a form of high-LET radiation, a reduction in the difference in radiosensitivity related to the position of the cells in the mitotic cycle, repair and clinical relevance of the different repair mechanisms Heavy ions and the advantage of better physical selectivity of protons with the radiobiological advantages of fast neutrons for some tumour types. as well as brachytherapy
| MSc level | | | This course is an introductory physics course> It is designed for student of non-physics majors. It focuses on basic physics concept and connections to everyday life. While advanced mathmatics is no t required for this course, basic math with some trigoand simple algebra is utilised. Proportional reasoning, estimating, and graphing skills are emphasized throughout the course.
the course includes the following topics; work in a straight line, motion in 2D, Newtons's law of motion. statics, work, energy and power, linear and angular momentum, temperature and the behaviour of gases, thermodynamics, thermal properties of matter. | UG level 2018/2019 | | | The aim of this course is to understand a number of fundemental physics principles included in the general physics (I) course by performing the following physical experiments: Analysis of Data, Measurements and Uncertainities, Vectors: Force Table, Kinematics of Rectilinear Motion, Force and Motion, Collisions in One Dimension, Simple Harmonic Motion - The Simple Pendulum, Ballistic Pendulum, Rotational Motion, Gas Laws, Specific Heat Capacity of Metals, and The Falling Sphere Viscometer. | UG level 2018/2019 |
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