Physics Of Diagnostic Radiology Made Easy

Mastering Medical Imaging Physics Of Radiology With Jeet Ghosh's Guide From Basic To Advance Level And Get Certification

What you'll learn

Electromagnetic Spectrum: Understanding the regions, significance, characteristics, and applications of the EM spectrum.

Electromagnetic Radiation: Exploring the characteristics, applications, and potential harmful effects of EM radiation.

X-Ray Production: Learning the steps, components of the X-ray tube, and factors like the heel effect and tube rating charts.

X-Ray Radiation: Gaining insights into types, discovery, characteristics, applications, and harmful effects of X-ray radiation.

Interactions of X-Rays with Matter: Studying primary interactions, their effects, and significance

X-Ray Beam Restrictors: Understanding types, applications, significance, and disadvantages.

X-Ray Grids: Learning about construction, ratio, frequency, types, functions, performance evaluation, grid cutoff, and air gap technique.

X-Ray Filters: Exploring types, construction, effects, and importance in imaging.

Intensifying Screens: Understanding fluorescence, phosphorescence, construction, functions, and maintenance.

PSP CR Screens: Learning about construction, working principles, types, functions, and handling.

Radiographic Image Quality: Studying contrast, quality factors, mottle, sharpness, and unsharpness

Fluoroscopic Imaging: Learning about intensifying screens, imaging characteristics, and pros and cons.

Radiographic Image Parameters: Studying contrast media, quality parameters, and mottle.

Radiation Protection: Understanding biological effects, units, exposure, dose limits, ALARA principle, and the inverse square law.

Digital Radiography: Learning about CR and DDR systems, their components, and working principles.

CT Physics: Exploring CT generations, MDCT, parts, slip ring technology, detectors, and reconstruction

USG Physics: Understanding USG components, transducers, imaging modes, and mechanisms.

MRI Physics: Learning about MRI components, working principles, safety, pulse echo sequences, image matrix, coils, cryogen, and quench.

Advanced Imaging Techniques: Overview of PET CT and PET MRI.

Exposure on Picture archiving and communication system (PACS) & DICOM (Digital Imaging and Communications in Medicine)

Requirements

Basic Understanding of Physics: A foundational knowledge of physics principles is helpful.

Medical Background: Some familiarity with medical terminology and basic anatomy can be beneficial.

Interest in Radiology: A keen interest in diagnostic radiology or medical imaging technology.

Educational Background: Typically, a high school diploma or equivalent; higher education in relevant fields (medicine, biology, engineering) is advantageous.

Computer Literacy: Ability to use computers and access online learning platforms, as the course may involve digital resources and tools.

Curiosity and Willingness to Learn: An eagerness to delve into the complexities of radiological physics and its applications.

Description

Unlock the secrets of medical imaging with "Physics of Diagnostic Radiology Made Easy." This meticulously designed course is perfect for aspiring radiologists, medical students, radiologic technologists, and healthcare professionals seeking a comprehensive and clear understanding of the fundamental physics principles that underpin diagnostic radiology.Why Enroll in This Course?In today’s fast-evolving medical landscape, proficiency in diagnostic radiology is indispensable. Our expertly crafted course simplifies complex concepts, making them accessible and easy to grasp. Whether you're a student aiming to excel academically or a professional seeking to enhance your expertise, this course will equip you with the knowledge and skills to master the intricacies of medical imaging physics.What You Will Learn:Exploring the Electromagnetic Spectrum : Understand the EM spectrum, including its regions, significance, characteristics, and applications in medical imaging.Understanding Electromagnetic Radiation : Learn the essentials of EM radiation, including its properties, practical applications, and potential harmful effects.X-Ray Radiation Overview : Discover the types, history, characteristics, and applications of X-ray radiation, as well as the associated risks.Journey to X-Ray Production : Explore the detailed steps of X-ray production, the components of the X-ray tube, and crucial concepts like the heel effect and tube rating charts.Interactions of X-Rays with Matter : Study the primary interactions of X-rays with matter, their effects, and their significance in medical imaging.X-Ray Beam Restrictors and Grids : Understand the types, applications, significance, and drawbacks of X-ray beam restrictors, as well as the construction, functions, and performance evaluation of X-ray grids.Magic of X-Ray Filters and Intensifying Screens : Learn about the types, construction, and effects of X-ray filters, and delve into intensifying screens, their functions, and maintenance.Flouroscopic Imaging & Image Intensifier: Learn about Image Intensifier,it's construction, working principle,phosphor , application,uses, advantages and disadvantage s of flouroscopic Imaging etc .Wonders of Digital Radiography: Lean about digital Radiography,direct and indirect radiography, PSP Screens and detectors, construction,working principle, applications, functioning, technology etc .Radiation Protection: Learn all the aspect of radiation safety need to protect you and patient with all the guidelines, ICRP principles, ALARA, radiation units, radiation dose, Personal monitoring devices TLD etc.Advanced Imaging Techniques DR | CT Scan | MRI | PET : Gain insights into the principles and components of digital radiography, CT, USG, and MRI, including advanced techniques like PET CT and PET MRI.Advance paperless storage , archiving and communication using PACS and DICOM : Gain insights levels , components and basic principles of PACS and DICOM .Course Highlights:Expert Instruction : Benefit from the knowledge and experience of industry professionals who provide practical insights and real-world examples.Comprehensive Curriculum : From fundamental principles to advanced imaging techniques, this course offers thorough and detailed coverage.Interactive Learning : Engage with interactive modules, practical exercises, and case studies designed to reinforce your understanding and application of the material.Flexible Schedule : Study at your own pace with our convenient online platform, allowing you to balance your education with your professional and personal commitments.Who Should Enroll?Medical Students : Build a strong foundation in radiology physics to excel in your studies and future career.Radiologic Technologists and Radiologists : Deepen your understanding and expertise in the physics of diagnostic imaging.Healthcare Professionals : Expand your knowledge and skills in medical imaging to improve patient care and outcomes.Biomedical Engineers and Technicians : Enhance your comprehension of the principles driving the technology you work with.Invest in Your Future:Enroll in "Physics of Diagnostic Radiology Made Easy" today and embark on a journey to mastering the essential physics of medical imaging. Empower yourself with the knowledge and skills necessary to excel in the dynamic field of diagnostic radiology.

Overview

Section 1: Module 1 : Basic Medical Physics of Diagnostic Radiology & Imaging technology

Lecture 1 Lesson 1 Lecture : Exploring The Electromagnetic Spectrum

Lecture 2 Lesson 2 Lecture : Understanding Electromagnetic Radiation

Lecture 3 Lesson 3 Lecture: X-Ray Radiation Overview

Lecture 4 Lesson 4 Lecture: Journey to X-Ray Production

Lecture 5 Lesson 5 Lecture: The Fascinating Interactions of X-rays with Matter

Lecture 6 Lesson 6 Lecture : X-ray Beam Restrictors Demystified

Lecture 7 Lesson 7 Lecture : Unmasking the X-Ray Grids

Lecture 8 Lesson 8 Lecture : Magic of X-Ray Filters

Lecture 9 Lesson 9 Lecture: Luminous Catalysts as Intensifying Screen

Lecture 10 Lesson 10 Lecture: Phosphorescent Pioneers PSP CR Screen

Lecture 11 Lesson 11 Lecture: Visual Symphony : Radiographic Image

Lecture 12 Lesson 12 Lecture : Geometry of Radiographic Image

Lecture 13 Lesson 13 Lecture: The Pulse Of Flouroscopic Imaging

Lecture 14 Lesson 14 Lecture: Depth Of Radiographic Protection

Section 2: Module 2 : Advance Medical Physics Of Diagnostic Radiology & Imaging Technology

Lecture 15 Lesson 15 Lecture: Wonders Of Digital Radiography

Lecture 16 Lesson 16 Lecture: Unveiling CT Scan Physics

Lecture 17 Lesson 17 Lecture: Easier USG Physics

Lecture 18 Lesson 18 Lecture: MRI Physics Made Easy

Lecture 19 Lesson 19 Lecture: Positron Emission Tomography ( PET Scan )

Lecture 20 Lesson 20 Lecture: PACS & DICOM

Section 3: Practice Test

Students doing PG Medical Courses Like - MD Radiology, DNB Radiology, DM Radio Diagnosis, Paramedical UG Courses like - BSc Medical Technology (Radiography and Imaging) , Diploma in Radiography Diagnostic Tech, MSc RIT and Other UG Medical Courses like MBBS,Medical Students: Those studying radiology, medical imaging, or related fields.,Radiologists: Practicing radiologists looking to refresh or deepen their knowledge of radiological physics.,Radiologic Technologists: Professionals seeking to enhance their understanding of the physics behind diagnostic radiology.,Medical Physicists: Individuals working in medical physics who want to specialize in diagnostic radiology.,Biomedical Engineers: Engineers who design and develop medical imaging equipment.,Healthcare Professionals: Nurses, physician assistants, and other healthcare providers interested in gaining a better understanding of diagnostic radiology.,Pre-med Students: Those preparing for a career in medicine, especially with a focus on radiology or diagnostic imaging.,Continuing Education Seekers: Professionals in the medical field looking for continuing education credits or professional development.,Anyone Interested: Anyone with a keen interest in understanding the principles of diagnostic radiology physics.