Postgraduate diploma Radiophysics Applied to Diagnostic Imaging

The generation of X-rays has been a major breakthrough in the follow-up of patients with chronic diseases. In this way, dynamic imaging systems enable experts to assess the function of moving organs, such as the heart. However, any exposure to ionizing radiation involves health risks for both patients and healthcare professionals. For example, expert handling of radiopharmaceuticals can result in radioactive contamination if nuclear material spills occur, it is therefore vital that radiological protection measures are taken. In this context, TECH has developed a 100% online program for nurses to keep up to date with dosimetric control and the international regulations that govern it.

University certificate

duration

6 months

Modality

Online

Schedule

At your own pace

Exams

Online

start date

Credits

18 ECTS

financing up to

7 months

Price(first year)

See price

The world's largest faculty of nursing”

Introduction to the Program

Dominarás el procesado de la imagen digital gracias a la mejor universidad digital del mundo, según Forbes”

El Efecto Compton es uno de los procesos más importantes que se deben tener presentes al calcular la dosis de radiaciones en los tratamientos. Los motivos radican en las implicaciones que tiene en la generación de imágenes médicas y en la dosificación de radiación en las diferentes terapias. Si los expertos incurriesen en errores a la hora de medir este proceso, se producirían desde diagnósticos incorrectos hasta una sobredosificación de radiaciones. A su vez, esto podría impulsar la aparición de efectos secundarios y daños en tejidos normales.

Para obtener una capacitación apropiada sobre la composición y densidad de los tejidos, TECH ha implementado este avanzado programa. Así, los enfermeros podrán llevar a cabo prácticas clínicas seguras, empleando tanto los Rayos X como los Rayos Gamma. De hecho, el plan de estudios abordará las interacciones que se producen entre los fotones y la materia.

Asimismo, se profundizará en los factores de ponderación de los órganos según su radiosensibilidad, analizando diversas herramientas para el control de calidad en los sistemas de visualización. Esto permitirá al egresado identificar los riesgos propios en el área hospitalaria y diseñar blindajes estructurales destinados a la protección, tanto de pacientes como del personal.

Con el objetivo de afianzar estos contenidos, la metodología del presente programa refuerza su carácter innovador. Así, TECH ofrece un entorno educativo 100% online, adaptado a las necesidades de los profesionales ocupados que buscan avanzar en sus carreras. Igualmente, emplea la metodología Relearning, basada en la repetición de conceptos clave para fijar conocimientos y facilitar el aprendizaje. De esta manera, la combinación de flexibilidad y un enfoque pedagógico robusto, lo hace altamente accesible. Además, los alumnos accederán a una amplia biblioteca de innovadores recursos multimedia en diferentes formatos audiovisuales, como resúmenes interactivos, vídeos explicativos, fotografías, estudios de caso e infografías.

Profundizarás en la interacción entre los fotones y materia para irradiar tumores con una elevada precisión”

Esta Postgraduate diploma en Radiophysics Applied to Diagnostic Imaging contiene el programa científico más completo y actualizado del mercado. Sus características más destacadas son:

El desarrollo de casos prácticos presentados por expertos en Radiofísica Aplicada al Diagnóstico por la Imagen
Los contenidos gráficos, esquemáticos y eminentemente prácticos con los que está concebido recogen una información científica y práctica sobre aquellas disciplinas indispensables para el ejercicio profesional
Los ejercicios prácticos donde realizar el proceso de autoevaluación para mejorar el aprendizaje
Su especial hincapié en metodologías innovadoras
Las lecciones teóricas, preguntas al experto, foros de discusión de temas controvertidos y trabajos de reflexión individual
La disponibilidad de acceso a los contenidos desde cualquier dispositivo fijo o portátil con conexión a internet

¿Buscar sacarles el máximo provecho a los equipos de Mamografía? Desarrolla las pruebas más avanzadas en el control de calidad, gracias a TECH”

El programa incluye en su cuadro docente a profesionales del sector que vierten en esta capacitación la experiencia de su trabajo, además de reconocidos especialistas de sociedades de referencia y universidades de prestigio.

Su contenido multimedia, elaborado con la última tecnología educativa, permitirá al profesional un aprendizaje situado y contextual, es decir, un entorno simulado que proporcionará una capacitación inmersiva programada para entrenarse ante situaciones reales.

El diseño de este programa se centra en el Aprendizaje Basado en Problemas, mediante el cual el profesional deberá tratar de resolver las distintas situaciones de práctica profesional que se le planteen a lo largo del curso académico. Para ello, contará con la ayuda de un novedoso sistema de vídeo interactivo realizado por reconocidos expertos.

Abordarás la calibración de dosímetros en detalle para garantizar mediciones confiables de la exposición a la radiación”

Con el sistema Relearning, pionero en TECH, reducirás las largas horas de estudio y memorización”

Syllabus

This program, consisting of 3 complete modules, will analyze the physical basis of radiation in order to understand how to measure personal dose. In this sense, the syllabus will establish the different dosimetric magnitudes, to be used in a variety of cases. Likewise, the didactic materials will address quality assurance protocols in imaging. In this way, nurses will apply measures aimed at maintaining the safety of the population exposed to medical radiation. The program will also delve into the magnitudes and specialized units of radiological protection.

You will be able to implement innovative technologies to evaluate and ensure the quality of the equipment used in Radiodiagnosis”

Module 1. Interaction of Ionizing Radiation with Matter

1.1. Radiation Ionizing-Matter Interaction

1.1.1. Ionizing Radiation
1.1.2. Collisions
1.1.3. Braking Power and Range

1.2. Charged Particle-Matter Interaction

1.2.1. Fluorescent Radiation

1.2.1.1. Characteristic Radiation or X-rays
1.2.1.2. Auger Electrons

1.2.2. Braking Radiation
1.2.3. Spectrum upon Collision of Electrons with a High Z Material
1.2.4. Electron-positron Annihilation

1.3. Photon-Matter Interaction

1.3.1. Attenuation
1.3.2. Hemireductive Layer
1.3.3. Photoelectric Effect
1.3.4. Compton Effect
1.3.5. Pair Creation
1.3.6. Predominant Effect according to Energy
1.3.7. Imaging in Radiology

1.4. Radiation Dosimetry

1.4.1. Charged Particle Equilibrium
1.4.2. Bragg-Gray Cavity Theory
1.4.3. Spencer-Attix Theory
1.4.4. Absorbed Dose in Air

1.5. Magnitudes in Radiation Dosimetry

1.5.1. Dosimetric Quantities
1.5.2. Radiation Protection Quantities
1.5.3. Radiation Weighting Factors
1.5.4. Weighting Factors of Organs according to their Radiosensitivity

1.6. Detectors for the Measurement of Ionizing Radiation

1.6.1. Ionization of Gases
1.6.2. Excitation of Luminescence in Solids
1.6.3. Dissociation of Matter
1.6.4. Detectors in the Hospital Setting

1.7. Dosimetry of Ionizing Radiation

1.7.1. Environmental Dosimetry
1.7.2. Area Dosimetry
1.7.3. Personal Dosimetry

1.8. Thermoluminescence Dosimeters

1.8.1. Thermoluminescence Dosimeters
1.8.2. Calibration of Dosimeters
1.8.3. Calibration at National Dosimetry Center

1.9. Physics of Radiation Measurement

1.9.1. Value of a Quantity
1.9.2. Accuracy
1.9.3. Precision
1.9.4. Repeatability
1.9.5. Reproducibility
1.9.6. Traceability
1.9.7. Quality in the Measurement
1.9.8. Quality Control of an Ionization Chamber

1.10. Uncertainty in Radiation Measurement

1.10.1. Uncertainty in the Measurement
1.10.2. Tolerance and Action Level
1.10.3. Type A Uncertainty
1.10.4. Type B Uncertainty

Module 2. Advanced Diagnostic Imaging

2.1. Advanced Physics in X-Ray Generation

2.1.1. X-ray Tubes
2.1.2. Radiation Spectra Used in Radiodiagnosis
2.1.3. Radiological Technique

2.2. Imaging in Radiology

2.2.1. Digital Image Recording Systems
2.2.2. Dynamic Imaging
2.2.3. Radiodiagnostic Equipment

2.3. Quality Control in Radiodiagnostics

2.3.1. Quality Assurance Program in Radiodiagnosis
2.3.2. Quality Protocols in Radiodiagnostics
2.3.3. General Quality Control Checks

2.4. Patient Dose Estimation in X-Ray Installations

2.4.1. Patient Dose Estimation in X-Ray Installations
2.4.2. Patient Dosimetry
2.4.3. Diagnostic Dose Reference Levels

2.5. General Radiology Equipment

2.5.1. General Radiology Equipment
2.5.2. Specific Quality Control Tests
2.5.3. Doses to Patients in General Radiology

2.6. Mammography Equipment

2.6.1. Mammography Equipment
2.6.2. Specific Quality Control Tests
2.6.3. Dose to Patients in Mammography

2.7. Fluoroscopy Equipment. Vascular and Interventional Radiology

2.7.1. Fluoroscopy Equipment
2.7.2. Specific Quality Control Tests
2.7.3. Dose to Patients in Interventions

2.8. Computed Tomography Equipment

2.8.1. Computed Tomography Equipment
2.8.2. Specific Quality Control Tests
2.8.3. Dose to Patients in CT

2.9. Other Radiodiagnostics Equipment

2.9.1. Other Radiodiagnostics Equipment
2.9.2. Specific Quality Control Tests
2.9.3. Non-ionizing Radiation Equipment

2.10. Radiological Image Visualization Systems

2.10.1. Digital Image Processing
2.10.2. Calibration of Display Systems
2.10.3. Quality Control of Visualization Systems

Module 3. Radiation Protection in Hospital Radioactive Facilities

3.1. Radiation Protection in Hospitals

3.1.1. Radiation Protection in Hospitals
3.1.2. Radiological Protection Magnitudes and Specialized Radiation Protection Units
3.1.3. Risks in the Hospital Area

3.2. International Radiation Protection Standards

3.2.1. International Legal Framework and Authorizations
3.2.2. International Regulations on Health Protection against Ionizing Radiation
3.2.3. International Regulations on Radiological Protection of the Patient
3.2.4. International Regulations on the Specialty of Hospital Radiophysics
3.2.5. Other International Regulations

3.3. Radiation Protection in Hospital Radioactive Facilities

3.3.1. Nuclear Medicine
3.3.2. Radiodiagnostics
3.3.3. Radiotherapy oncology

3.4. Dosimetric Control of Exposed Professionals

3.4.1. Dosimetric Control
3.4.2. Dose Limits
3.4.3. Personal Dosimetry Management

3.5. Calibration and Verification of Radiation Protection Instrumentation

3.5.1. Calibration and Verification of Radiation Protection Instrumentation
3.5.2. Verification of Environmental Radiation Detectors
3.5.3. Verification of Surface Contamination Detectors

3.6. Tightness Control of Encapsulated Radioactive Sources

3.6.1. Tightness Control of Encapsulated Radioactive Sources
3.6.2. Methodology
3.6.3. International Limits and Certificates

3.7. Design of Structural Shielding in Medical Radioactive Facilities

3.7.1. Design of Structural Shielding in Medical Radioactive Facilities
3.7.2. Important Parameters
3.7.3. Thickness Calculation

3.8. Structural Shielding Design in Nuclear Medicine

3.8.1. Structural Shielding Design in Nuclear Medicine
3.8.2. Nuclear Medicine Facilities
3.8.3. Calculation of the Workload

3.9. Structural Shielding Design in Radiotherapy

3.9.1. Structural Shielding Design in Radiotherapy
3.9.2. Radiotherapy Facilities
3.9.3. Calculation of the Workload

3.10. Structural Shielding Design in Radiodiagnostics

3.10.1. Structural Shielding Design in Radiodiagnostics
3.10.2. Radiodiagnostics Facilities
3.10.3. Calculation of the Workload

You will analyze real clinical cases, bringing the development of the program as close as possible to the reality of health care”

Postgraduate Diploma in Radiophysics Applied to Diagnostic Imaging

Immerse yourself in a transformative educational experience with the Postgraduate Diploma in Radiophysics Applied to Diagnostic Imaging in the nursing field, offered by TECH Global University. This postgraduate program represents a unique opportunity for committed professionals seeking to excel in the fascinating world of medical diagnostics, combining the flexibility of online classes with the educational excellence of TECH. As academic leaders in the healthcare sector, we understand that contemporary nursing requires a combination of specialized knowledge and practical skills. Our innovative approach qualifies you in advanced diagnostic imaging techniques, giving you the tools you need to lead in specialized nursing settings. Online classes, designed to fit your schedule, allow you to advance your education without compromising your professional responsibilities. In addition, our innovative Relearning methodology amplifies your cognitive abilities in record time, helping you to more easily internalize complex concepts and skills.

Boost your nursing career with this postgraduate program in radiophysics

Our team of experts in applied radiophysics will guide you through the fundamentals and latest innovations in diagnostic imaging. From mastering radiological equipment to advanced interpretation of results, this program prepares you to meet complex challenges in patient care. At TECH, we offer you not only theoretical knowledge, but also the opportunity to apply your skills in real-world situations. Upon completion of this program, you will not only earn a diploma as a University Expert in Radiophysics, but you will stand out as a leader in the integration of advanced technologies into nursing practice. You'll be prepared to address today's challenges in diagnostic imaging and contribute to the continued advancement of healthcare. Take the next step in your career with TECH Global University and be part of the next generation of nurses specializing in radiophysics applied to diagnostic imaging. Enroll today and discover a new horizon of possibilities for your professional growth!