Introduction to the Program

Thanks to this 100% online Postgraduate certificate, you will optimize Radiotherapy and Nuclear Medicine treatments while ensuring patient safety”

Biomedical Imaging is a crucial element for the early diagnosis of multiple pathologies and for monitoring the effectiveness of treatments. For example, in Oncology, imaging can show changes in the size or appearance of tumors, reflecting the response to the applied therapies. In this context, healthcare professionals need to stay at the forefront of the latest advancements in this field. One of the latest trends is Computed Tomography, which is used to determine the extent of a disease and monitor treatments.

Therefore, TECH Global University develops a pioneering program in Medical Physics. The academic curriculum will thoroughly analyze natural and artificial radiation sources, addressing factors such as charged particle accelerators. The syllabus will also delve into Reconstruction Algorithms to generate medical images and use them to detect anomalies early. In addition, the teaching materials will focus on handling Biomedical Imaging to evaluate treatment effectiveness and make adjustments to the treatment strategy as needed. Furthermore, the program will address the importance of the Fourier Transform for processing medical images.

It is important to note that this university program stands out for its 100% online methodology. This format will provide specialists with the flexibility needed to adapt to their professional schedules. Additionally, TECH Global University employs the Relearning methodology, based on the repetition of key concepts, to consolidate knowledge and facilitate effective learning. As such, the combination of accessibility and innovative pedagogical approach will ensure that professionals acquire practical skills. All experts need to access the Virtual Campus is an electronic device with internet access, whether using their own mobile phone, computer, or tablet.

Acquire the most advanced techniques for Biomedical Image Reconstruction at the world’s best digital university, according to Forbes”

This Postgraduate certificate in Medical Physics contains the most complete and up-to-date program on the market. The most important features include:

  • Practical case studies are presented by experts in Physics
  • The graphic, schematic and eminently practical contents with which it is conceived gather scientific and practical information on those disciplines that are indispensable for professional practice
  • Practical exercises where the self-assessment process can be carried out to improve learning
  • Its special emphasis on innovative methodologies
  • Theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments
  • Content that is accessible from any fixed or portable device with an Internet connection

You will explore the modules of this program through the revolutionary Relearning methodology, quickly and flexibly incorporating its most complex concepts”

The program’s teaching staff includes professionals from the industry who contribute their work experience to this program, as well as renowned specialists from leading societies and prestigious universities.

Its multimedia content, developed with the latest educational technology, will allow the professional a situated and contextual learning, that is, a simulated environment that will provide an immersive learning programmed to prepare for real situations.

The design of this program focuses on Problem-Based Learning, where the professional will need to address various practical situations presented throughout the academic program. For this purpose, students will be assisted by an innovative interactive video system created by renowned experts.

You will delve into Reconstruction Algorithms to generate detailed medical images that contribute to the precise planning of treatments”

You will master the Planar Gamma Scintigraphy technique to visualize the three-dimensional distribution of radionuclides within the human body”

Syllabus

Through this university program, engineers will gain a comprehensive understanding of the underlying physical principles in emerging technologies. To achieve this, the academic curriculum will delve into the interaction between radiation and matter. In line with this, the program will equip students with the most advanced techniques for obtaining biomedical images, applying improvements through histogram modifications. Additionally, the syllabus will explore the Monte Carlo Simulation technique, allowing graduates to optimize treatment plans to maximize the dose delivered to the tumor while minimizing the dose to surrounding healthy tissues.

You will acquire the most sophisticated techniques to optimize the quality of medical images, minimizing radiation exposure and maximizing the diagnostic information obtained”

Module 1. Medical Physics

1.1. Natural and Artificial Radiation Sources

1.1.1. Alpha, Beta and Gamma Emitting Nuclei
1.1.2. Nuclear Reactions
1.1.3. Neutron Sources
1.1.4. Charged Particle Accelerators
1.1.5. X-Ray Generators

1.2. Radiation-Matter Interaction

1.2.1. Photon Interactions (Rayleigh and Compton Scattering, Photoelectric Effect and Electron-Positron Pair Creation)
1.2.2. Electron-Positron Interactions (Elastic and Inelastic Collisions, Bremsstrahlung Radiation Emission, and Positron Annihilation)
1.2.3. Ion Interactions
1.2.4. Neutron Interactions

1.3. Monte Carlo Simulation of Radiation Transport

1.3.1. Pseudo-Random Number Generation
1.3.2. Drawing Techniques
1.3.3. Radiation Transport Simulation
1.3.4. Practical Examples

1.4. Dosimetry

1.4.1. Dosimetric Quantities and Units (ICRU)
1.4.2. External Exposure
1.4.3. Radionuclides Incorporated in the Body
1.4.4. Radiation-Matter Interaction
1.4.5. Radiological Protection
1.4.6. Permitted Limits for the Public and Professionals

1.5. Radiobiology and Radiotherapy

1.5.1. Radiobiology
1.5.2. External Radiotherapy with Photons and Electrons
1.5.3. Brachytherapy
1.5.4. Advanced Treatment Methods (Ions and Neutrons)
1.5.5. Planning

1.6. Biomedical Imaging

1.6.1. Biomedical Imaging Techniques
1.6.2. Image Enhancement through Histogram Modification
1.6.3. Fourier Transform
1.6.4. Filtering
1.6.5. Restoration

1.7. Nuclear Medicine

1.7.1. Tracers
1.7.2. Detection Equipment
1.7.3. Gamma Camera
1.7.4. Planar Scintigraphy
1.7.5. SPECT
1.7.6. PET (Polyethylene Terephthalate)
1.7.7. Small Animal Equipment

1.8. Reconstruction Algorithms

1.8.1. Radon Transform
1.8.2. Central Slice Theorem
1.8.3. Filtered Back Projection Algorithm
1.8.4. Noise Filtering
1.8.5. Iterative Reconstruction Algorithms
1.8.6. Algebraic Algorithm (ART)
1.8.7. Maximum Likelihood Estimation Algorithm (MLE)
1.8.8. Ordered Subsets (OSEM)

1.9. Biomedical Image Reconstruction

1.9.1. SPECT Reconstruction
1.9.2. Degrading Effects Associated with Photon Attenuation, Scattering, System Response, and Noise.
1.9.3. Compensation in Filtered Back Projection Algorithm
1.9.4. Compensation in Iterative Methods

1.10.  Radiology and Nuclear Magnetic Resonance (NMR)

1.10.1. Radiology Imaging Techniques: X-ray and CT
1.10.2. Introduction to NMR
1.10.3. NMR Imaging
1.10.4. NMR Spectroscopy
1.10.5. Quality Control

Make the most of this opportunity to surround yourself with expert professionals and learn from their work methodology”

Postgraduate Certificate in Medical Physics

The Postgraduate Certificate in Medical Physics, created by TECH Global University, is a highly relevant educational option for those interested in exploring the fascinating field where physics and medicine intersect. This program, offered entirely online, provides specialized training in the fundamental principles and practical applications of physics in the medical field, preparing you to work successfully in areas such as radiotherapy, medical imaging, dosimetry, and radiation protection. Throughout this program, key topics such as ionizing radiation, its biological effects, the design and operation of medical equipment like linear accelerators and MRI (Magnetic Resonance Imaging) systems, as well as advanced dosimetry techniques and dose calculation in radiotherapy treatments, will be thoroughly explored. One of the standout advantages of this program is its practical and applied approach. Through a theoretical-practical focus, you will develop technical and analytical skills to work effectively in medical environments and collaborate with interdisciplinary health teams.

Specialize in medical physics

The online format of this course offers flexibility and accessibility, allowing you to study from anywhere and adapt your learning schedule to your professional and personal responsibilities. Additionally, you will have access to multimedia resources, virtual classes, and interactive tools that will enhance your educational experience and allow you to apply the knowledge gained to real-world situations. The teaching team consists of experts in medical physics, radiotherapy, and advanced medical technologies, who provide support and guidance throughout the course. Upon completion of the program, you will receive a recognized certificate that validates your specialized training and opens doors to professional opportunities in hospitals, clinics, research centers, and companies in the healthcare sector, contributing to the advancement and innovation of evidence-based, scientific, and technological medicine. Make the decision and enroll now!