This report details curricular recommendations for graduate degrees in medical physics and serves as an update to Report No. 197. In this section, we review the history of American Association of Physicists in Medicine (AAPM) curricular recommendations, present the aims of this report, and detail how these recommendations should be interpreted.

The first AAPM publication on curricular recommendations for graduate education in medical physics was AAPM Report No. 44, published in 1993, describing the recommendations for the Master of Science Degree in Medical Physics.¹ AAPM Report No. 79 was published in 2002 and established a core curriculum for all graduate training in medical physics, as well as more specific education and training associated with the individual subspecialties in medical physics.² In 2009, Report No. 79 was updated and published as AAPM Report No. 197, and in 2011, AAPM Report No. 197S was published on the essential didactic elements for alternative pathway entrants into the clinical medical physics profession.^3,4 Report No. 197S defined the curriculum for a postdoctoral certificate program in medical physics, the first of which was accredited by Commission on Accreditation of Medical Physics Education Programs (CAMPEP) in 2011. The AAPM Working Group on the Revision of Report No. 44 was initially created with the charge of periodically reviewing and updating the recommended curriculum for medical physics graduate education programs. In 2012, the AAPM renamed this as the Working Group on Medical Physics Graduate Education Program Curriculum (WGMPGEPC). The WGMPGEPC was further charged to ensure that the graduate education curriculum reflects current needs of clinical practice and provides a broad foundation upon which to base future innovations. The profession of medical physics has undergone substantial growth and change over the years since the publication of Report No. 197 in 2009, and the WGMPGEPC has updated the curricular recommendations to reflect these changes and prepare the profession for the future.

There exists a common core of similar coursework across all programs accredited by the Commission on Accreditation of Medical Physics Education Programs, Inc. (CAMPEP), yet each program has the latitude to adapt its curriculum to best leverage the strengths and resources of its faculty and host institution. The number of CAMPEP-accredited graduate programs has more than doubled since the publication of Report No. 197, increasing from 24 in 2009 to over 50 in 2021. A common goal of the AAPM curriculum recommendations is to ensure that the core curriculum meets the current and anticipated future needs of the medical physics profession. The curriculum recommendations in this report support these aims in three ways. They provide guidance to graduate programs in medical physics regarding the topics that should be covered in their curricula. They provide guidance to instructors regarding the breadth of coverage of relevant topics. Finally, they provide a basis for developing standards for graduate medical physics education. The curriculum provides substantial detail within the topics provided for each section. This is primarily to assist graduate programs and course instructors, and it is not our intention to recommend that any accrediting or supervisory body would expect that a program would cover every item explicitly mentioned in the curriculum. A bibliography of suggested resources, categorized by topical area, is included, and entries are duplicated, as appropriate, when relevant to multiple topical areas.

There is a considerable degree of intellectual diversity of students entering graduate programs, including previous degree(s) earned, courses taken, and topics previously learned. The recommendations on graduate medical physics curricula in this report are designed to apply to all students. However, individual programs should determine whether to give credit to incoming students with previous course work that fulfills didactic medical physics training requirements (e.g., previous study of anatomy and physiology).

One major change since the publication of Report No. 197 is the requirement to complete an accredited residency training program to gain knowledge and skills needed to practice independently as a qualified medical physicist and to acquire professional board certification. The residency increases the amount of practical clinical training by at least 2 years, yet there remains a substantial benefit to providing practical learning experiences during graduate education. Benefits of this include baseline learning for all students (including those who pursue nonclinical careers, e.g., in industry and government), reinforcement of didactic learning, enhanced preparedness for clinical research, and preparedness to enter residency training. It is important for programs to design curricula to strike an appropriate balance between theoretical coursework and practical experiences. Graduate programs should provide ample opportunities for practical, hands-on experiential learning in the clinical and laboratory environments. The practical learning experiences appropriate to graduate education are narrower in scope, more selective in topics, and more limited in time when compared with those of a residency program. Although many practical clinical topics are explicitly mentioned in this curriculum, it is left to the individual program to determine the breadth and depth of coverage.

The graduate certificate program remains an important part of the medical physics training infrastructure as the didactic medical physics preparation for alternative pathway entrants into medical physics practice. AAPM Report No. 197S defined the essential elements of this didactic preparation. As Report No. 365 supersedes Report No. 197, it also provides guidance to supersede the supplemental Report No. 197S. The topics defined here as Sections 2.1.1–2.1.10 represent the core elements identified during the development of this report. Topics in Sections 2.1.1–2.1.6 match those identified as essential didactic elements in Report No. 197S; however, their content has been updated. Topics in Sections 2.1.7–2.1.9 (“mathematical and statistical methods”, “computational methods and medical informatics”, and “research methods”) are the ones that may have been covered in the prior training of individuals entering the profession through the alternative pathway. Situations requiring remediation may or may not require the completion of full courses. This leaves topic in Section 2.1.10, “professionalism (leadership, ethics, communication),” as the notable addition to the recommendations of Report No. 197S. Report No. 197S recommended a curriculum, including a minimum of 18 credit hours of didactic coursework. Report No. 365 recommends the minimum curricular recommendations from Report No. 197S plus the delivery of training in professionalism. This may increase the credit hour requirements for programs that deliver this training within a formal didactic course. The AAPM recently commissioned a task group on Alternative Pathway Candidate Education and Training (TG-298) to provide updated recommendations for the alternative pathway.⁵ Although Report No. 365 aims to provide overarching curricular recommendations for all graduate education programs in medical physics, TG-298 aims to provide recommendations on the education and training of alternative pathway entrants into the medical physics profession. One important recommendation from TG-298 is that programs provide clinical experience and exposure to the application of the didactic material. This recommendation provides support for the emphasis of practical clinical training within graduate education programs. A related recommendation by TG-298 is that online delivery of curricular material should be carefully evaluated to assure that it does not limit the student's exposure to experiential, clinical aspects of medical physics. Lastly, TG-298 recommends that programs include ethics and professionalism as a component of their core curriculum. We have included those components in the recommendations in this report.

The first professional doctorate degree in medical physics (DMP) was created in 2009 and accredited by CAMPEP in 2010. The DMP includes the same core curricular elements as the MS and PhD in medical physics and therefore does not warrant substantial changes in the curricular recommendations for graduate medical physics education. The DMP does provide additional opportunities and incentives for the inclusion of elective coursework that may be valuable for clinical practice, such as business and management coursework. These additional courses and others may also be valuable for students not intending to pursue clinical careers. Finally, DMP curricula must include clinical training of sufficient depth and breadth to prepare the student to become a qualified medical physicist. This training is the purview of other reports such as AAPM Report No. 249⁶ and Report No. 373⁷ and is not within the scope of this report.

An aim of the recommendations on graduate curricula presented in this report is to identify the salient topical areas of medical physics graduate education required to prepare trainees for current and future practice in this profession. As such, current technology, techniques, and methodology are often explicitly identified. It is, however, often instructive for trainees to understand historical aspects of medical physics technology and practice in order to understand the evolution of our practice and help guide its future. Such historical context is not always explicitly mentioned within this curriculum. However, it is assumed to be incorporated within medical physics graduate education where useful for the benefit of our trainees.

Similarly, another aim of this report is to prepare students and programs to adapt to future changes in the scope and nature of medical physics applications. This report represents a snapshot of current education and training requirements; however, we must also equip students with the education and skills necessary to contribute to, and be leaders of, future advances in medicine. Future contributions of physicists to medicine are often driven by understanding and training outside of traditional core topics. As such, training in nontraditional areas facilitates potential future contributions to science and medicine in general, and this emphasis has been explicitly incorporated into this curriculum. We should aspire to train our students to be multidisciplinary experts who are leaders in the science of medicine, who ensure the highest quality care and safety, and who initiate and create changes that enhance patient care. Incorporating these aspects and others that will arise in the future requires an increase in the breadth of education and training in medical physics. Programs should minimally strive to provide familiarity in these nontraditional areas, as it would be impossible to provide mastery in them all. Instilling critical thinking and lifelong learning skills will allow medical physicists to continue to enhance their ability to contribute to the science of medicine. Many nontraditional topics as well as applications of didactic material may be provided within seminar and/or practical application courses. Graduate programs are not expected to develop specific expertise in all of these areas, but outside lecturers and material developed by other departments and/or programs may be leveraged to fill these gaps.

The recognition that graduates from medical physics graduate programs may choose to enter nonclinical careers has encouraged the creation and promotion of didactic elements of graduate education aimed at best preparing those who enter nonclinical careers. The AAPM created the Working Group to Promote Non-Clinical Career Paths for Medical Physicists in 2016, and the Working Group for Non-Clinical Professionals in 2018. In order to address the educational needs of some nonclinical careers, in particular industrial career paths, we have included education and training in “Industry and Regulatory” as a component of the curricular recommendations in this report. It should be emphasized, however, that these training elements would also benefit those medical physicists that choose clinical career paths, as many of the challenges (e.g., interaction with industry, good business practices) are areas of essential strength of clinical medical physicists as well.

The provision of training in research is an important element in preparing for the future of our profession. Indeed, the AAPM description of the role of the medical physicist states that “medical physicists play a vital and often leading role on the medical research team.” This includes both basic and clinical research and the problem-solving skills of the medical physicist. As such, we must provide the medical physics student with more than knowledge. We must provide the understanding that allows them to think beyond the present, to do more than just prescriptive problem-solving, and to innovate and solve previously unsolved problems. Additionally, medical physicists have not been sufficiently integrated into clinical trials research in the past, particularly in leadership roles, which has often negatively impacted the quality of clinical research. Specific recommendations for such training are provided in this report that addresses particular areas of research training. In addition, every effort should be made to foster critical thinking skills throughout the education and training of future entrants into our profession, as this is a distinguishing feature of a medical physicist and one that makes us valuable to the medical profession.

Finally, this report is primarily intended to provide recommendations on what to teach rather than how to teach it. The recommended depth of understanding for each topic is not specifically prescribed here, and it is left to the individual program to determine, for each recommended topic, whether mere familiarity is sufficient or whether deep understanding and mastery of a topic is warranted. The application of Bloom's taxonomy or other models to classify educational learning objectives is helpful in determining specific goals for competence.⁸ We also do not recommend specific courses but rather curricular content presented within topical areas. As there can be significant overlap between topical areas, we have attempted to simplify the report by assigning particular curricular elements to only one topical area and referencing them to that area from others in which they may be relevant. Finally, we make no recommendations on pedagogical aspects of graduate education, including how or when material is provided. Discussion of the merits or application of online coursework, flipped classrooms, or other aspects related to the cognitive science involved in developing and delivering education is not included here.

Section 2 provides a description for each of the sections within the report, whereas Section 3 provides detailed curricular recommendations where applicable. Sections 2.1 and 3.1 provide recommended core topics, whereas Sections 2.2 and 3.2 provide additional (optional) topics. Sections 2.3–2.7 and 3.3–3.7 represent professional specializations (diagnostic imaging, nuclear medicine, radiation therapy [RT], medical health physics, and industry). These respective sections provide curricular recommendations for students specializing in each of these professional practice areas. These areas are denoted as optional and some programs do not provide an option for specialization.

DATA AVAILABILITY STATEMENT

Data sharing is not applicable to this article as no new data were created or analyzed in this study.

An understanding of the structure of matter and the manner in which ionizing radiation interacts with it is critical to the application of radiation to imaging, nuclear medicine (NM), RT, and health physics. This material builds off concepts of modern physics and is recommended within an introductory course to serve as a foundation for many of the other sections contained within this curriculum. The primary learning objectives include an understanding of individual interaction mechanisms, including both the physics involved in describing the probability for each interaction and the way in which energy is dissipated in the interaction. The student should be able to apply these concepts to all particles of interest, including uncharged particles (photons and neutrons) and charged particles (electrons, protons, alpha particles, etc.) with the ability to analyze differences between the mechanisms involved in charged and uncharged particle interactions. The physics and mathematics of radioactive decay should be understood along with all decay mechanisms. A broad understanding of the measurement of radiation, specifically including the measurement of absorbed dose, should be attained, including radiation dosimetry concepts, techniques, and equipment. This should include concepts such as radiation equilibria, cavity theory, microdosimetry, and all quantities and relationships involved. Finally, the student should be familiar with the various types of radiation dosimetry equipment, along with their mechanisms of operation and limitations.

Radiation protection and safety pervades the various subspecialties of medical physics. Although technologies will change, having a fundamental understanding of how radiation works and how to protect oneself and others are crucial principles to the medical physics profession. A comprehensive study of radiation protection and safety could be structured by providing the answers to these major questions: Why does radiation need to be managed? What can you do to manage radiation exposure? How can you detect radiation? How much exposure can you safely receive? For whom is this important? How can you develop a safety culture? By posing these questions, a broad spectrum of topics can be discussed, including fundamental physics interactions, biological effects of radiation, and basic principles of radiation protection. Special attention is given to protection and safety of the radiation worker, patients, the public, and the environment. It is important to consider the present regulatory environment and the interactions with the recommendations from multiple organizations outside of the AAPM. Complementary tutorial instruction could include a sequence of laboratory experiences focusing upon radiation detection instrumentation, shielding methodology, and clinical applications for radiation protection and safety. The emphasis in this topic is to provide a broad knowledge base of radiation safety and protection supportive of the varied environments of medical physics practice.

Medical imaging is a foundational component of medical physics and has been developed and advanced over decades to become a cornerstone of healthcare. Because of the ubiquitous use of imaging, all medical physicists need a working knowledge of key imaging physics concepts. The core competencies presented in this section include concepts of image processing, image display and image quality; image reconstruction from projections; and the key hardware, software, and operational details of each imaging modality. These modalities are projection X-ray imaging (radiography, mammography, and fluoroscopy), volumetric X-ray imaging (computed tomography [CT], cone-beam CT, and tomosynthesis), nuclear imaging (scintigraphy, single-photon emission CT, and positron emission tomography [PET]), ultrasound imaging (echo 2D and 3D imaging, and Doppler imaging), and magnetic resonance imaging (MRI). The details listed for each core competency indicate the minimum depth of coverage. The core competencies presented in this section can be supplemented by application-specific knowledge about targeted use of imaging technologies, whether for imaging or therapeutic applications.

RT is a foundational component of medical physics, with 2/3 of all cancer patients receiving RT and numerous applications for RT for nonmalignant conditions. Medical physicists in all disciplines should have basic familiarity with the clinical, technological, and radiobiological concepts involved in RT. The significant overlap of imaging and NM with RT and the associated potential for collaborative work across these specialties underscores the need for cross-disciplinary training. The core elements of RT are presented here, including clinical and radiobiological principles, equipment and technology used for RT, specific treatment techniques and principles of radiation protection and quality management. The information presented here should ideally be supplemented by practical exposure to these technologies and techniques in the clinical environment.

All subspecialties of medical physics require an understanding of the biological effects of radiation. Specifically, radiobiological principles comprise foundational knowledge in underpinning theories of radiation protection, RT, radiation imaging of humans, and NM. Radiobiology provides the basic connection between microscopic and molecular interactions of radiation with cellular and tissue responses. This material provides a solid biological and physiological background for understanding the effects of radiation on human tissues and cancers and the resulting safety policies and therapy regimens. These topics should be presented in a cohesive and consistent manner, not distributed among subspecialty applications such as RT physics, imaging physics, radiation protection and safety, and NM.

Anatomy and physiology underpin the entirety of medical physics. Familiarity with normal anatomy is fundamental to radiotherapy treatment planning and medical imaging optimization. Cancer biology must also be understood at a basic level, as it drives many aspects of RT and medical imaging. Key linking concepts can be covered where they exist, such as cardiotoxicity from radiotherapy and the link between normal glucose metabolism and PET imaging. An organ system approach is logical for presenting the content in this section, with particular emphasis on normal imaging appearance, common imaging tasks related to pathology, and disease sites related to radiotherapy.

Competency in mathematical methods is foundational to the understanding of medical imaging, radiological physics, and dosimetry. Incoming graduate students should have a strong background in mathematics demonstrated by their undergraduate or graduate coursework. Medical physics graduate training should enhance the understanding of mathematical techniques as they relate to medical imaging, computational science, and optimization. Graduate training should also provide a foundation in statistical methods as it relates to experimental design and analysis.

It is becoming increasingly important that medical physicists possess a working knowledge of computational methods and informatics. Graduate curricula should include the basics of programming and machine learning as they relate to the many potential applications in medical physics. They should also include informatics as it relates to medical image storage and transfer. These skills could be developed through opportunities to practice implementation such as class projects, assignments, and research.

Students should be exposed to and participate in research and be familiar with research methods, ethics, and scientific communication, which includes academic writing, reviewing, and presentation. In addition, protocol and grant writing, clinical translation/implementation, literature search and reading, and laboratory management are important skills with which students should become familiar. As the experience a student gains from their research endeavors will vary depending on individual advisors and projects, programs should consider how to ensure the consistency of development of research skills across all students. The delivery of a seminar series, such as journal clubs or presentations from students, faculty, and invited speakers is one useful mechanism for the development of research skills. Although all formats should expose students to a breadth of current research topics, different formats inevitably emphasize different skills such as literature review, communication and scientific presentation skills, and others. Programs should keep this in mind when designing the seminar format to give students the opportunity to develop all of these skills. Programs that do not require a thesis project or a seminar series should consider how their students will develop the skills traditionally associated with such offerings. Alternatives practiced by some programs include class projects, laboratory sections, “special topics” courses focused on current literature and research, and student attendance at scientific conferences. Finally, exposure to areas such as clinical trials, grant/protocol writing, laboratory management, and clinical translation/implementation may be best acquired via a faculty advisor/mentor and is perhaps more suitable in a PhD program. As the certificate program pathway is open only to individuals holding a PhD degree, it is anticipated that these research requirements would have been fulfilled prior to entry into the certificate program.

The medical physicist will be routinely involved in interactions with professional colleagues, collaborating clinicians, trainees, patients, research subjects, administrators, and/or support staff, to name just a few. In all such interactions, a number of critical skills must be applied. First and foremost, the medical physicist must understand the ethical obligations and responsibilities of this role. As many medical physicists will be involved in leadership and management within the hospital and university setting, as well as serving as the de facto leader of the technical, quality, and safety aspects of a clinical department, the development of leadership skills is very important. These skills allow the medical physicist to have an appropriate and sufficient influence within these areas, for example, to influence the safety culture of a clinical department. Good communication skills are critical for leadership as well as for patient and clinician interactions. Such skills not only enhance leadership capabilities but also efficiency and accuracy in clinical collaboration as well as facilitating the most effective patient care.

Radiation biology and anatomy and physiology are essential for medical physics competency. However, additional training in biology subfields can provide further competency both for research and in clinical practice, enhancing the ability of medical physicists to contribute to medical science and practice in general. Some example areas include biochemistry and biomolecules, cardiology, computational biology, epidemiology, genomics, immunology, neurobiology, oncology, pathology, and clinical pharmacology. Although it would be impossible to include all of these topics within a graduate program in medical physics, familiarity with these topics, along with preparation in health science terminology, helps medical physicists better communicate with clinicians and other research scientists and contribute more integrally to clinical and research efforts. This additional training further facilitates the identification and exploration of nontraditional applications of medical physics and thus expands our contribution to medicine.

Elective coursework provides students with the opportunity to broaden their understanding of related fields or deepen their knowledge of medical physics specialties. Advanced physics disciplines of interest to the medical physicist may include nuclear physics, electricity and magnetism, optics, and solid state physics. Engineering coursework can be found in the biomedical, nuclear, electrical and computer engineering disciplines. Computer science electives should focus on topics to prepare medical physicists to be effective collaborators within the scientific community. Example coursework may cover statistical software packages, team programming practices, including version control and best practices for readability, and artificial intelligence.

Frontiers in medical physics represent areas in which physics has begun to contribute to the improvement of medical care and/or has the potential to further improve human health. In RT, examples include FLASH, RT for non-cancer treatments (e.g., cardiac ablation), radiomics, interplay with other therapies (e.g., immunotherapy, photodynamic therapy [PDT]). In imaging, examples include radiomics and theranostics, interferometry imaging, biophotonics, magnetoencephalography, and alternative (monochromatic) X-ray sources. In NM, examples include novel radiotracer development for radiomics and theranostics. Additional opportunities outside medical physics represent areas outside the current landscape of medical physics practice. Areas for potential involvement include surgery (image guidance), pathology (image display, automation), ophthalmology (optical modeling), dentistry (3D modeling), orthopedics (motion analysis), cardiology (electrophysiology), neuroscience, and psychology. There is no expectation that any particular program cover these materials, rather this functions as a survey of potential topics. Incorporation of these topics in a specific program should reflect that program's strengths and research.

Medical physics as a profession has multiple facets that often interact and overlap with business principles in a wide range of areas. Although it is not necessary to have an intricate knowledge of business aspects, it is important to be able to effectively communicate in these areas. As with all roles, the effectiveness of the function of medical physics is based on sound business decisions being made. A medical physicist may find use for these skills working in a clinic, working for a vendor, or working in a physics consulting company. In addition, any medical physicist functioning in a leadership role will eventually require business skills. A medical physicist's role will ultimately determine the level of knowledge that is required, whether it be large commercial operations or a single consultant. As such, the skills below are a broad cross section of areas that will provide a foundation for this knowledge, and the topics are intended as a baseline dependent on the demands of the individual's situation. Many of these business skills are strongly correlated with, and can be considered simply another facet of, skills outlined in other sections of this curriculum.

Effective teaching is an increasingly important skill for all medical physicists. Indeed, medical physicists are often asked to teach within medical physics, RT technology, dosimetry, and residency programs and to provide training in-services for other clinicians. As such, it is valuable for medical physicists to have an understanding of adult learning theory and the different educational pedagogies that may be used. As teachers tend to teach in the manner in which they were taught, the most effective way to teach students about different methodologies along with the potential advantages and disadvantages of different pedagogies is not to lecture about them, but rather to have students experience those pedagogies firsthand in the classroom. Physics Education Research has clearly shown that didactic lecture, while being the most efficient for the lecturer, is likely the least effective method of teaching for the majority of physics students. The more active and hands-on the pedagogy, the more engaging and effective the time spent in class. However, it has also been shown that alternate pedagogies can sometimes take significantly more time to cover the same amount of material as a traditional didactic lecture. This means that there is still value in a well-prepared and well-delivered lecture. The topics listed here provide methods designed to create the most effective learning environment for the student.

Medical imaging is a foundational component of medical physics. Every medical physicist must master core competencies, including the principles of image formation, imaging hardware and software, and the optimization and constraining of the imaging process. However, those physicists specializing in diagnostic imaging (DI) require additional depth in imaging physics theory and practical applications. The topical outline here replicates and extends the outline provided in fundamentals of imaging. This enhanced knowledge includes the principal concepts for each DI modality: projection X-ray imaging (radiography, mammography, and fluoroscopy), volumetric X-ray imaging (CT, cone-beam CT, and tomosynthesis), ultrasound imaging (echo and transmission 2D, 3D, and Doppler imaging), MRI (MRI methods and spectroscopy), and information technology (picture archive and communication system [PACS], displays, EMR, and safety and quality monitoring). The nuclear imaging specialization (planar, single-photon emission CT, and PET) is described in a separate section, although there is substantial overlap in many topics. The training of a DI physicist must also incorporate experiential knowledge gained through hands-on practical activities, as they pertain to optimal use of imaging technologies in the clinic, including quality assurance (QA), applications, and processes to customize a procedure to the patient. The clinical priority is to enable and ensure optimized, reliable, quantitative, and safe use of the imaging technologies.

The work of NM physicists spans radionuclide production, radiation protection, scanner operation (including calibration, maintenance, and QC), image reconstruction, and image analysis (including tracer kinetic modeling) and creating new hardware and algorithms for NM applications. Although most physicists’ jobs do not entail all of these components, it is important that basic NM physics education be broad because of both the different job opportunities that exist and their fundamental interrelatedness. NM inherently draws on the related contributions of physicists, chemists, pharmacists, physicians, technologists, and others. Some familiarity with the other professionals’ disciplines can be beneficial for the physicist as part of the interdisciplinary team and essential for understanding NM in general. NM physics education should cover the principles, devices, and algorithms used in the field. A broad background provided in medical physics core topics is essential. It is widely regarded that therapeutic applications of NM will continue to increase and that more patient-specific dosimetry, specifically based on imaging/therapeutic compound pairs, will be warranted, providing a good opportunity for broadly trained NM physicists. Much NM physics (especially that related to the imaging devices) is performed by physicists practicing in DI. From an educational perspective, a physicist broadly engaged in NM, whether as a DI physicist or as a dedicated NM physicist (or even as an RT physicist), should have the in-depth NM didactic background recommended in this section.

RT is a foundational component of medical physics. As such, medical physicists in all disciplines should have basic familiarity with the clinical, technological, and radiobiological concepts involved in RT. This section provides both the historical background and fundamental bases for the therapeutic use of ionizing radiation, along with a detailed description of the equipment and techniques used in modern RT, including all aspects necessary for clinical practice in radiation oncology. The wide variety of radiation sources, the technology associated with production and delivery of this radiation, and the clinical characteristics and utility of the various modalities used for RT are presented. The information presented here should be supplemented by practical exposure to these technologies and techniques in the clinical environment.

Health physics is a distinct profession with its own training programs, curricula, and professional society (Health Physics Society). Health physics contains subtopics, however, that are germane to medical physicists. Content from radiation physics, detection, and dosimetry; radiation protection and safety; and radiation biology is especially fundamental to many medical health physics topics. Although that content is fundamental, medical health physics students will need the greater depth covered here.

Roles in industry and regulatory agencies require a diverse set of skills and knowledge to be able to effectively collaborate with team members with backgrounds that may differ substantially from those in a clinical environment. This sector of potential employment is critical in translating research/academic concepts to a product that can be put into clinical use. Often there is some mystery surrounding roles in this sector due to the variety of opportunities. Additionally, some of the topics suggested may be unfamiliar to candidates who have specialized in science. It is suggested that knowledge levels in these areas are attained to the understanding level of Bloom's taxonomy as an introduction to industry. The proposed topic lists are not exclusive nor comprehensive, and the content within these topics will differ over time as the landscape in this field changes rapidly. In addition, it should be noted that some subject areas are US specific; however, they could be adapted for other countries. It is, however, strongly recommended that any candidate who is considering a role in this sector gain awareness in each of these topics. With that said, it is also important to note that there is extensive detail within each of these topics, some having their own full degree programs associated with them. The goal should always be to have enough peripheral knowledge to conduct daily workplace operations unassisted and understand when it is necessary to reach out to experts in the respective topic.

• Review of atomic and nuclear structure

• Atomic structure, electron shells, electron shell filling, electron binding energy, electron excitation, and models of the atom

• Nuclear structure, nucleons, nucleon binding energy, nuclear excitation, nuclear stability, and models of the nucleus

• Unstable structures, line of nuclear stability, radioactive decay and de-excitation

• Management of radiation risk

• Rationale for the management of radiation risk

• Examples of management strategies for radiation risk

• Examples of past radiation incidents and events

• Radiation physics and detection for imaging

• Fundamentals of digital image processing

• Linear systems

• Discrete signal processing

• Pixel-based operations: window, leveling, subtraction, and thresholding

• Convolution and spatial domain filtering for smoothing and enhancement

• Fourier-space filtering

• Magnification, interpolation, deformation, and registration

• Segmentation

• Analysis (e.g., similarity, cross-correlation, texture, and shape)

• Compression; lossy and lossless methods

• Overview of clinical oncology

• Cancer incidence/etiology

• Cancer classification/staging

• Overview of oncology treatment modalities

• Radiation injury to DNA

• Radiation chemistry of water

• Structure of DNA and types of radiation-induced lesions

• Double-strand breaks

• Radiation dosimetry, microdosimetry, and ionization density and their relationship to DNA damage

• Language of anatomy

• Planes

• Projections

• Imaging conventions

• Landmarks

• Homeostasis

Mathematical methods

• 1.

  Math background

• Fermi-type estimation problems (e.g., how to estimate input data if it is not readily available and recognition of the uncertainties caused by these estimations)

• The complex plane, odd/even functions

• Algorithm complexity and basic linear algebra subroutines (BLAS)

• Entropy and information gain

Statistical methods

• 6.

  Descriptive statistics

• Scales of measurement of observations: nominal, ordinal, interval, ratio

• Univariate and multivariate observations

• Distributions of observations (e.g., normal, binomial, lognormal, Poisson, and Gaussian)

• Population parameters versus sample statistics

• Distribution of statistics, random sampling

• Graphical methods (e.g., box plots, probability plots, Loess plots, and time series)

• Quality control statistics, univariate and multivariate control charts

• Moments: expectation, mean, and variance

Computational methods

• 1.

  Basic computer skills

• Spreadsheet software, word processor, presentation software, and PDF editor

• Search engine syntax, journals (e.g., Pubmed, Google Scholar)

• Image viewing and processing software

Medical informatics

• 6.

  Networking

• Types of networks, data rate, and bandwidth

• Network infrastructure

• Wide area network, local area network

• Communication protocols: TCP/IP and OSI Models

• Cloud storage

• Literature search and reading

• Research methods and documentation

• Academic writing, reviewing, and presentation

• Clinical trials

• Protocol and grant writing

• Clinical translation and implementation

• Laboratory management

Leadership

• 1.

  Personal and interpersonal

• Emotional self-awareness

• Adaptability, initiative, and empathy

• Organizational awareness and service orientation

• Influence, conflict management, teamwork, and collaboration

Ethics and professionalism

• 4.

  Ethical principles and values

• 5.

  Medical ethics

• Ethical definitions and historical context

• Ethics in the era of modern science

• Nuremberg Code, Declaration of Helsinki, Belmont Report

Communication

• 9.

  Scientific communication

• Scientific writing

• Scientific presentation

• Public education

• Radiation Therapy

• Radiomics, theranostics; connection to genomics and other -omics

• Immunotherapy + RT

• RT for non-cancer treatments (e.g., cardiac ablation)

• FLASH

• Cerenkov imaging (applications for RT, proton and heavy ion therapy)

• Chemotherapy + RT

• PDT + RT

• High-intensity focused ultrasound + RT

• Tumor-treating fields

• Clinical

• Medical physics–specific charges

• Clinical roles and operation (from a business perspective)

• Systems-based practice

• Licensing (differences between states)

• Purchase agreements (e.g., service and support contracts)

• Best teaching practices

• Traditional pedagogies

• Assessment and evaluation

• Teaching critical thinking

• Clinical teaching and mentoring

• Online teaching and learning

• Blended learning

• Open textbooks and online resources

• Radiation physics and detection for imaging

• Core topics from radiological physics and dosimetry (Section 3.1.1)

• Photon interactions relevant to imaging

• Radiation detectors used in imaging

• Basic physics

• Basic atomic and nuclear physics

• Modes of radioactive decay

• Radioactive decay rates, including transient and secular equilibrium

• Passage of radiation through matter

• Clinical radiation oncology

• Cancer etiology, classification, and staging

• Cancer statistics (incidence, survival and hazard functions, proportional hazards model, and Kaplan–Meier analysis)

• Overview of oncology treatment modalities

• Core topics from radiobiology (Section 3.1.5) and anatomy and physiology (Section 3.1.6)

• Radiobiological basis of RT

• Workflow of clinical oncology and radiation oncology

• Biological effects of radiation

• Core topics from radiobiology (Section 3.1.5) and radiation protection and radiation safety (Section 3.1.2)

• Patient dose assessment and dose reconstruction (examples): for example, fluoroscopic skin dose, fetal dose, and RAM administrations

• Patient dose tracking (examples): regulatory and accreditation requirements, significant radiation dose level, and diagnostic reference levels

Product creation

• 1.

  Market research and strategy

• Strategic marketing (e.g., vision, mission, purpose, strategy, objective)

• Global RT and radiology demands

• Industry trends/direction

Regulatory and legal

• 5.

  Regulatory

• Federal and state regulations on radiation-producing devices and nuclear byproducts

• Regulatory requirements and public safety

• Regulatory requirements on X-ray imaging and mammography systems

• Storage, handling, and transport of nuclear byproducts

• FDA clearance, approval, and medical device classes

• 510(k) premarket notification and substantial equivalence

• Compliance controls

Policy in medical physics

• 8.

  Policy and government

• Definitions of policy, politics, policy analysis, advocacy, and activism

• Types of policy (public, social, health, institutional, and organizational)

• Spheres of political action in medical physics (government, workplace, professional societies, and community)

• Structure, processes, and power of all three branches of the US government

• Enactment of laws (bills and resolutions, authorizing vs. appropriating legislation)

• Litigation and liability in the context of medical physics

• Role of state governments in certification of medical physicists

• International health-care strategy (e.g., role of IAEA, World Health Organization)

Note: Some titles listed here are out of print but have been retained in this list due to their important historical role in medical physics education. Every effort has been made to list additional alternatives to these texts and instructors are encouraged to assure that students have access to all texts recommended by the instructor for a given course.

• Evans RD. The Atomic Nucleus. McGraw-Hill Company; 1955.
• Johns HE, Cunningham JR. The Physics of Radiology. 4th ed. Charles C Thomas; 1983.
• Knoll GF. Radiation Detection and Measurement. 4th ed. John Wiley & Sons; 2010.
• Podgorsak EB. Radiation Physics for Medical Physicists. Springer-Verlag; 2005.
• Attix FH. Introduction to Radiological Physics and Radiation Dosimetry. John Wiley & Sons; 2008.
• Andreo P, Burns DT, Nahum AE, Seuntjens J, Attix FH. Fundamentals of Ionizing Radiation Dosimetry. John Wiley & Sons; 2007.
• Turner JE. Atoms, Radiation, and Radiation Protection. 3rd ed. Wiley; 2017.

• Hall EJ, Giaccia AJ. Radiobiology for the Radiologist. 8th ed. Lippincott Williams & Wilkins; 2018.
• National Research Council. Health Risks from Exposure to Low Levels of Ionizing Radiation: BEIR VII Phase 2. The National Academies Press; 2006.
• National Research Council. Health Effects of Exposure to Radon: BEIR VI. The National Academies Press; 1996.
• Cember H. Introduction to Health Physics. 3rd ed. McGraw-Hill; 1996.
• Attix FH. Introduction to Radiological Physics and Radiation Dosimetry. John Wiley & Sons; 2008.
• Knoll GF. Radiation Detection and Measurement. John Wiley & Sons; 2010.
• Stabin MG. Radiation Protection and Dosimetry: An Introduction to Health Physics. Springer Science & Business Media; 2007.
• McGinley PH. Shielding Techniques for Radiation Oncology Facilities. Medical Physics Publishing; 1998.
• American Society for Radiation Oncology. Safety Is No Accident – A Framework for Quality Radiation Oncology Care. American Society for Radiation Oncology; 2019.
• American Institute of Physics. AAPM Report No. 283. “The Report of Task Group 100 of the AAPM: Application of Risk Analysis Methods to Radiation Therapy Quality Management”. American Institute of Physics; 2016.
• International Commission on Radiological Protection. Recommendations of the ICRP. ICRP publication 26. Ann ICRP. 1977;1(3):3-6.
• International Commission on Radiological Protection. Report of Committee II on Permissible Dose for Internal Radiation. ICRP Publication 2. Pergamon Press; 1960.
• National Council on Radiation Protection and Measurements. NCRP Report No. 147 – Structural Shielding Design for Medical X-Ray Imaging Facilities. National Council on Radiation Protection and Measurements; 2005.
• National Council on Radiation Protection and Measurements. NCRP Report No. 151 – Structural Shielding Design and Evaluation for Megavoltage X- and Gamma-Ray Radiotherapy Facilities. National Council on Radiation Protection and Measurements; 2005.
• US Nuclear Regulatory Commission (NRC) Title 10, CFR Part 19–70.
• US DOT Rule 49 CFR Part 300–399, 198.
• Current Federal Regulations, including US Nuclear Regulatory Commission (NRC), US DOT, FDA, Occupational Safety and Health Administration (OSHA), US Public Health Services (PHS), and USEPA

• Bushberg JT, Seibert JA, Leidholt EM, Boone JM. The Essential Physics of Medical Imaging. 4th ed. Lippincott Williams and Wilkins; 2020. ISBN 978-1975103224.
• Samei E, Peck DJ. Hendee's Physics of Medical Imaging. 5th ed. Wiley-Blackwell; 2019. ISBN 978-0470552209.
• Gonzalez RC, Woods RE. Digital Image Processing. 4th ed. Pearson; 2017. ISBN 978-0133356724.
• Cherry SR, Sorenson JA, Phelps ME. Physics of Nuclear Medicine. 4th ed. Elsevier Saunders; 2012. ISBN: 978-1416051988.
• Bailey DL, Humm JL, Todd-Pokropek A, van Aswegan A, eds. Nuclear Medicine Physics: A Handbook for Teachers and Students. IAEA; 2014. ISBN: 978-9201438102.

• Hendee WR, Ibbott GS, Hendee EG. Radiation Therapy Physics. 3rd ed. Wiley-Liss; 2004.
• Johns HE, Cunningham JR. The Physics of Radiology. 4th ed. Charles C Thomas; 1983.
• Khan FM. The Physics of Radiation Therapy. 4th ed. Lippincott Williams and Wilkins; 2009.
• McDermott PN, Orton CG. The Physics & Technology of Radiation Therapy. 2nd ed. Medical Physics Publishing; 2018.
• Podgorsak EB. Radiation Oncology Physics: A Handbook for Teachers and Students. IAEA; 2005.
• Rubin P, Bakemeier RF. Clinical Oncology for Medical Students and Physicians: A Multidisciplinary Approach. 5th ed. American Cancer Society; 1978.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Medical Physics Publishing; 1999.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Vol 2. Medical Physics Publishing; 2005.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Vol 3. Medical Physics Publishing: 2013.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Vol 4. Medical Physics Publishing; 2020.

• Hall EJ, Giaccia AJ. Radiobiology for the Radiologist. 8th ed. Lippincott Williams & Wilkins; 2018.
• Joiner MC, van der Kogel AJ. Basic Clinical Radiobiology. 5th ed. CRC Press; 2018.
• Mettler FA, Upton AC. Medical Effects of Ionizing Radiation. Saunders/Elsevier; 2008.
• National Research Council. Health Risks from Exposure to Low Levels of Ionizing Radiation: BEIR VII Phase 2. The National Academies Press; 2006.
• National Council on Radiation Protection and Measurements. NCRP Report No. 150 – Extrapolation of Radiation-Induced Cancer Risks from Nonhuman Experimental Systems to Humans. National Council on Radiation Protection and Measurements; 2005.
• National Council on Radiation Protection and Measurements. NCRP Report No. 160 – Ionizing Radiation Exposure of the Population of the United States. National Council on Radiation Protection and Measurements; 2009.
• National Council on Radiation Protection and Measurements. NCRP Report No. 181 – Evaluation of the Relative Effectiveness of Low-Energy Photons and Electrons in Inducing Cancer in Humans. National Council on Radiation Protection and Measurements; 2018.
• National Council on Radiation Protection and Measurements. NCRP Report No. 184 – Medical Radiation Exposure of Patients in the United States. National Council on Radiation Protection and Measurements; 2019.
• Weinberg RA. The Biology of Cancer. 2nd ed. Garland Science; 2013.

• Betts JG, DeSaix P, Johnson E, et al. Anatomy and Physiology. OpenStax; 2013. ISBN 1938168135.
• Fleckenstein P, Tranum-Jensen J. Anatomy in Diagnostic Imaging. 3rd ed. Wiley-Blackwell; 2014. ISBN 978-1-118-50048-4.
• Hanahan D, Weinberg RA. Hallmarks of Cancer: The Next Generation. Cell. 2011;144:646-674.
• Nelson DL, Cox MM. Lehninger Principles of Biochemistry. 8th ed. Macmillan; 2021. ISBN 9781319230906.
• Marieb EN, Brady PM, Mallatt JB. Human Anatomy. 9th ed. Pearson; 2020. ISBN 978-0135168059.
• Marieb EN, Hoehn KN. Human Anatomy & Physiology. 11th ed. Pearson; 2019. ISBN 978-1292261034.
• Weinberg RA. The Biology of Cancer. WW Norton; 2013. ISBN 978-0-815-34529-9.
• Ellis H, Logan BM, Dixon AK, Bowden DJ. Human Sectional Anatomy. 4th ed. CRC Press; 2017. ISBN 978-1498708548.
• Ferrier DR, Champe PC, Harvey RA. Lippincott Illustrated Reviews: Biochemistry. 7th ed. Wolters-Kluwer; 2017. ISBN 9781496344496.
• Alberts B, Johnson A, Lewis J, Morgan D, Raff M, Roberts K, Walter P. Molecular Biology of the Cell. 6th ed. Garland Science; 2015. ISBN 978-0815345244. (Note: 4th edition available on NCBI Bookshelf: https://www.ncbi.nlm.nih.gov/books/NBK21054/)
• Nelson DL, Cox MM, Hoskins AA. Lehninger Principles of Biochemistry. 8th ed. Macmillan Learning; 2021. ISBN 978131932238.
• e-Anatomy. https://doi.org/10.37019/e-anatomy

• Altman DG. Practical Statistics for Medical Research. Chapman & Hall; 1995.
• Arfken GB, Weber HJ. Mathematical Methods for Physicists. Academic Press; 1995.
• Armitage P, Berry G. Statistical Methods in Medical Research. 3rd ed. Blackwell Scientific Publishing; 1994.
• Bailar JC III, Mosteller F, eds. Medical Uses of Statistics. 2nd ed. New England Journal of Medicine; 1992.
• Berry DA, Stangl DK. Bayesian Biostatistics. Marcel Dekker; 1996.
• Box GEP, Hunter WG, Hunter JS. Statistics for Experimenters. An Introduction to Design, Data Analysis, and Model Building. John Wiley & Sons; 1978.
• Bracewell R. The Fourier Transform and Its Applications. 3rd ed. McGraw-Hill Science/Engineering/Math; 1999.
• Byrne CL. Signal Processing: A Mathematical Approach. 2nd ed. CRC Press; 2015.
• Chow S, Liu J. Design and Analysis of Clinical Trials. Concepts and Methodologies. John Wiley & Sons; 1998.
• Collett D. Modelling Survival Data in Medical Research. Chapman & Hall; 1994.
• Everitt BS, Pickles A. Statistical Aspects of the Design and Analysis of Clinical Trials. Imperial College Press; 1999.
• Hastie T, Tibshirani R, Friedman J. The Elements of Statistical Learning – Data Mining, Inference, and Prediction. 2nd ed. Springer; 2009.
• James G, Witten D, Hastie T, Tibshirani R. An Introduction to Statistical Learning: with Applications in R. Springer; 2013.
• Kochenderfer MJ, Wheeler TA. Algorithms for Optimization. The MIT Press; 2019.
• Kreyszig EO. Introductory Functional Analysis with Applications. Wiley; 1989.
• McCullagh P, Nelder JA. Generalized Linear Models. 2nd ed. Chapman & Hall; 1989.
• Montgomery DC, Peck EA. Introduction to Linear Regression Analysis. 2nd ed. John Wiley & Sons; 1992.
• Oppenheim AV, Schafer RW. Discrete-Time Signal Processing. Prentice Hall; 1989.
• Rosner B. Fundamentals of Biostatistics. 8th ed. Cengage Learning; 2015.
• Verhulst F. Nonlinear Differential Equations and Dynamical Systems. Springer-Verlag; 1990.

• AAPM. AAPM Report No. 201. “Quality Management of External Beam Therapy Data Transfer”. American Association of Physicists in Medicine; 2021.
• Branstetter BF. Practical Imaging Informatics: Foundations and Applications for PACS Professionals. Springer; 2010.
• Bushberg JT, Seibert JA, Leidholt EM Jr, Boone JM. The Essential Physics of Medical Imaging. 3rd ed. Lippincott Williams & Wilkins; 2012.
• Clark N. Computer Programming for Beginners: Fundamentals of Programming Terms and Concepts. CreateSpace Independent Publishing Platform; 2018.
• Ng, Andrew. DeepLearning.AI Programs. https://www.deeplearning.ai/programs/. (Accessed 9/28/2022)
• Manly BFJ. Randomization, Bootstrap and Monte Carlo Methods in Biology. 2nd ed. Chapman & Hall; 1997.
• Samei E, Peck DJ. Hendee's Physics of Medical Imaging. 5th ed. Wiley-Blackwell; 2019.
• Starkschall G, Siochi RAC. Informatics in Radiation Oncology. CRC Press; 2014.
• Samei E, Pfeiffer DE. Clinical Imaging Physics: Current and Emerging Practice. Wiley-Blackwell; 2020.
• Verhaegen F, Seco J. Monte Carlo Techniques in Radiation Therapy. CRC Press; 2016.

Leadership

• Medical Physics Leadership Academy website: www.aapm.org/leadership/ (Accessed 9/29/2022)
• Kouzes JM, Posner B. The Leadership Challenge: How to Make Extraordinary Things Happen in Organization. 6th ed. Wiley and Sons, Inc.; 2017.
• McCraven WM. Make Your Bed: Little Things That Can Change Your Life…And Maybe the World. Grand Central Publishing; 2017.
• Barabás AL. The Formula: The Universal Laws of Success. Hachette Book Group, Inc.; 2018.
• Maxwell J. Developing the Leader Within You 2.0. Harper Collins; 2018.
• Goleman D. Working with Emotional Intelligence. Bantam Books; 2006.
• Bradberry T, Greaves J, Lencioni PM. Emotional Intelligence 2.0. TalentSmart; 2009.
• The Arbinger Institute. The Anatomy of Peace: Resolving the Heart of Conflict. Berrett-Koehler Publishers; 2015.
• Patterson K, Grenny J, McMillan R, Switzler A. Crucial Conversations: Tools for Talking When Stakes are High. McGraw-Hill Education; 2002.
• Covey S. The 7 Habits of Highly Effective People. Simon & Schuster; 2012.
• Burns JM. Leadership. Open Road Media; 2012.
• Adams L. The Loyalist Team: How Trust, Candor, and Authenticity Create Great Organizations. PublicAffairs; 2017.
• Goleman D. Emotional Intelligence: Why It Can Matter More than IQ. Bloomsbury Publishing; 1996.
• Covey S. Principle-Centered Leadership. Simon & Schuster; 1992.
• Smith P. Lead with a Story: A Guide to Crafting Business Narratives That Captivate, Convince, and Inspire. AMACOM; 2012.
• Carnegie D. How to Win Friends and Influence People. Pocket Books; 1998.
• Blanchard K, Johnson S. The One Minute Manager. William Morrow & Company; 2003.
• Larson CE, LaFasto FMJ. Teamwork: What Must Go Right/What Can Go Wrong. Sage Publications; 1989.
• Pfeffer J. Managing With Power: Politics and Influence in Organizations. Harvard Business School Press; 1992.

Ethics & professionalism

• American College of Medical Physics, Code of Ethics. http://www.acmp.org/org/code_of_ethics.asp
• American College of Radiology, Code of Ethics. http://www.acr.org/MainMenuCategories/about_us/committees/ethics/code_of_ethics.aspx
• Code of Medical Ethics, American Medical Association. http://www.ama-assn.org/ama/pub/category/2498.html
• The Nuremberg Code. https://history.nih.gov/research/downloads/nuremberg.pdf
• World Medical Association Declaration of Helsinki – Ethical Principles for Medical Research Involving Human Subjects. https://www.wma.net/policies-post/wma-declaration-of-helsinki-ethical-principles-for-medical-research-involving-human-subjects/
• U.S. Department of Health and Human Services, Office for Human Research Protections. https://www.hhs.gov/ohrp/regulations-and-policy/index.html
• U.S. Department of Health and Human Services, Office for Human Research Protections, The Belmont Report. https://www.hhs.gov/ohrp/regulations-and-policy/belmont-report/index.html
• National Institutes of Health. http://www.history.nih.gov/laws%5Chtml%5Cbelmont.htm
• U.S. Department of Health and Human Services, Office for Human Research Protections, Health Information Privacy. https://www.hhs.gov/hipaa/index.html
• Office of Research Integrity. http://ori.dhhs.gov/
• National Education Association code of ethics. http://www.nea.org/aboutnea/code.html
• AAPM/RSNA Onlines Modules on Ethics and Professionalism. https://www.aapm.org/education/webbasedmodules.asp
• Skourou C, Sherouse GW, Bahar N, et al. Code of ethics for the American Association of Physicists in Medicine (Revised): report of Task Group 109. Med Phys. 2019;46(4):e79-e93.
• Serago CF, Burmeister JW, Dunscombe PB, et al. Recommended ethics curriculum for medical physics graduate and residency programs: report of Task Group 159. Med Phys. 2010;37(8):4495-4500.
• Tavani HT. Ethics & Technology: Ethical Issues in an Age of Information and Communication Technology. John Wiley & Sons, Inc.; 2007.
• Hogstrom K, Horton J. Introduction to the Professional Aspects of Medical Physics. University of Texas MD Anderson Cancer Center; 1999.
• Brennan T, Blank L, Cohen J, et al. Medical professionalism in the new millennium: a physician charter. Ann Intern Med. 2002;136:243-246.

Communication

• Penrose AM, Katz SB. Writing in the Sciences: Exploring Conventions of Scientific Discourse. The St. Martin's Press; 1998.
• Hogstrom KR, Horton JL. Introduction to the Professional Aspects of Medical Physics. The University of Texas M.D. Anderson Cancer Center; 1999.
• Epstein RM, Street RL. Patient-Centered Communication in Cancer Care. National Cancer Institute, NIH Publication No. 07-6225; 2007.

• Starkschall G. Editorial: Medical physicists as educators. J Appl Clin Med Phys. 2009;10(3):1-2.
• Mazur E. Peer Instruction: A User's Manual. Prentice-Hall Inc.; 1997.
• Redish EF. Teaching Physics: with the Physics Suite. John Wiley & Sons; 2004. Available free online at http://www2.physics.umd.edu/~redish/Book/
• Defined Learning. What is Project-Based Learning? website; 2019. https://www.definedstem.com/blog/what-is-project-based-learning/
• Buck Institute for Education. What is PBL? website; 2019. https://www.pblworks.org/what-is-pbl
• Kry S. Best practices: flipped learning in the medical physics classroom. Presentation from the 2018 AAPM Workshop on Improving the Teaching and Mentoring of Medical Physics. AAPM Virtual Library. Available on the AAPM website at: https://www.aapm.org/education/VL/vl.asp?id=12667
• Howell R. Best practices: project-based learning (PBL) in medical physics. Presentation from the 2018 AAPM Workshop on Improving the Teaching and Mentoring of Medical Physics. AAPM Virtual Library. Available on the AAPM website at: https://www.aapm.org/education/VL/vl.asp?id=12661
• Knowles M. The Adult Learner: A Neglected Species. 3rd ed. Gulf Publishing; 1984.
• Webster RS. In defence of the lecture. Aust J Teach Educ. 2015;40(10). Available online at https://files.eric.ed.gov/fulltext/EJ1078748.pdf.
• Armstrong P. Bloom's Taxonomy. website; 2021. https://cft.vanderbilt.edu/guides-sub-pages/blooms-taxonomy/
• National Research Council. How People Learn: Brain, Mind, Experience, and School. National Academy Press; 2000.

• Bushberg JT, Seibert JA, Leidholt EM, Boone JM. The Essential Physics of Medical Imaging. 4th ed. Lippincott Williams and Wilkins; 2020. ISBN 978-1975103224.
• Samei E, Peck DJ. Hendee's Physics of Medical Imaging. 5th ed. Wiley-Blackwell; 2019. ISBN 978-0470552209.
• Prince JL, Links JM. Medical Imaging Signals and Systems. 2nd ed. Pearson; 2014. ISBN 978-0132145183.
• Epstein CL. Introduction to the Mathematics of Medical Imaging. 2nd ed. SIAM; 2008. ISBN 978-0898716429.
• Barrett HH, Meyers KJ. Foundations of Image Science. John Wiley & Sons; 2004. ISBN 978-0471153009.
• Deans SR. The Radon Transform and Some of Its Applications. Dover Publications; 2007. ISBN 978-0486462417.
• Jain AK. Fundamentals of Digital Image Processing. Pearson; 1988. ISBN 978-0133361650.
• Gonzalez RC, Woods RE. Digital Image Processing. 4th ed. Pearson; 2017. ISBN 978-0133356724.
• Knoll GF. Radiation Detection and Measurement. 4th ed. John Wiley & Sons; 2010. ISBN 978-0470131480.
• Hsieh J. Computed Tomography: Principles, Design, Artifacts, and Recent Advances. 3rd ed. SPIE Press; 2015. ISBN 978-1628418255.
• Bushong SC, Clarke G. Magnetic Resonance Imaging: Physical and Biological Principles. 4th ed. Mosby; 2014. ISBN 978-0323073547.
• Nishimura D. Principles of Magnetic Resonance Imaging. Lulu; 2010.
• Brown RW, Chieng Y-CN, Haacke EM, Thompson MR, Venkatesan R. Magnetic Resonance Imaging: Physical Principles and Sequence Design. 2nd ed. Wiley Blackwell; 2014. ISBN 978-0471720850.
• National Council on Radiation Protection and Measurements. NCRP Report No. 147. “Structural Shielding Design for Medical X-ray Imaging Facilities”. National Council on Radiation Protection and Measurements; 2004. ISBN 0929600835.

• Cherry SR, Sorenson JA, Phelps ME. Physics of Nuclear Medicine. 4th ed. Elsevier Saunders; 2012. ISBN: 978-1416051988.
• Bailey DL, Humm JL, Todd-Pokropek A, van Aswegan A, eds. Nuclear Medicine Physics: A Handbook for Teachers and Students. IAEA; 2014. ISBN: 978-9201438102.
• Loevinger R, Budinger TF, Watson EE. MIRD Primer for Absorbed Dose Calculations. Society of Nuclear Medicine; 1991. ISBN: 0-932004385.
• Sgouros G, Bodei L, McDevitt M, Nedrow JR. Radiopharmaceutical therapy in cancer: clinical advances and challenges. Nat Rev Drug Discovery. 2020;19(9):589-608.
• Madsen MT, Anderson JA, Halama JR, et al. AAPM Task Group 108: PET and PET/CT shielding requirements. Med Phys. 2006;33(1):4-15.
• Knoll GF. Radiation Detection and Measurement. 4th ed. Wiley; 2010. ISBN: 978-0470131480.
• Volterrani D, Erba PA, Carrió I, Strauss HW, Mariani G. Nuclear Medicine Textbook. Springer; 2019. ISBN: 978-3-319-95564-3.
• Sandler MP, Coleman RE, Patton JA, Wackers FJTh, Gottschalk A. Diagnostic Nuclear Medicine. 4th ed. Lippincott, Williams & Williams; 2003. ISBN: 978-0781732529.
• IAEA. Nuclear Medicine Resources Manual 2020 Edition, Human Health Series No. 37. IAEA; 2020.

• AAPM. AAPM Report No. 17. “The Physical Aspects of Total and Half Body Photon Irradiation”. American Institute of Physics; 1986.
• AAPM. AAPM Report No. 23. “Total Skin Electron Therapy: Technique and Dosimetry”. American Institute of Physics; 1987.
• AAPM. AAPM Report No. 46. “Comprehensive QA for Radiation Oncology”. American Institute of Physics; 1994.
• AAPM. AAPM Report No. 51. “Dosimetry of Interstitial Brachytherapy Sources”. American Institute of Physics; 1995.
• AAPM. AAPM Report No. 54. “Stereotactic Radiosurgery”. American Institute of Physics; 1995.
• AAPM. AAPM Report No. 59. “Code of Practice for Brachytherapy Physics: Report of the AAPM Radiation Therapy Committee Task Group No. 56”. American Institute of Physics; 1997.
• AAPM. AAPM Report No. 62. “American Association of Physicists in Medicine Radiation Therapy Committee Task Group 53: Quality Assurance for Clinical Radiotherapy Treatment Planning”. American Institute of Physics; 1998.
• AAPM. AAPM Report No. 67. “AAPM's TG-51 protocol for clinical reference dosimetry of high-energy photon and electron beams”. American Institute of Physics; 1999.
• AAPM. AAPM Report No. 76. “AAPM Protocol for 40–300 kV X-Ray Beam Dosimetry in Radiotherapy and Radiobiology”. American Institute of Physics; 2001.
• AAPM. AAPM Report No. 91. “The Management of Respiratory Motion in Radiation Oncology”. American Institute of Physics; 2006.
• AAPM. AAPM Report No. 99. “Recommendations for Clinical Electron Beam Dosimetry: Supplement to the Recommendations of Task Group 25”. American Institute of Physics; 2009.
• AAPM. AAPM Report No. 100. “Acceptance Testing and Quality Assurance Procedures for Magnetic Resonance Imaging Facilities”. American Institute of Physics; 2010.
• AAPM. AAPM Report No. 101. “Stereotactic Body Radiation Therapy: The Report of AAPM Task Group 101”. American Institute of Physics; 2010.
• AAPM. AAPM Report No. 106. “Accelerator Beam Data Commissioning Equipment and Procedures: Report of the TG-106 of the Therapy Physics Committee of the AAPM”. American Institute of Physics; 2008.
• AAPM. AAPM Report No. 119. “IMRT Commissioning: Multiple Institution Planning and Dosimetry Comparisons, a Report from AAPM Task Group 119”. American Institute of Physics; 2009.
• AAPM. AAPM Report No. 142. “Task Group 142 Report: Quality Assurance of Medical Accelerators”. American Institute of Physics; 2009.
• AAPM. AAPM Report No. 148. “QA for Helical Tomotherapy: Report of the AAPM Task Group 148”. American Institute of Physics; 2010.
• AAPM. AAPM Report No. 218. “Tolerance Limits and Methodologies for IMRT Measurement-Based Verification QA: Recommendations of AAPM Task Group No. 218”. American Institute of Physics; 2018.
• AAPM. AAPM Report No. 263. “Standardizing Nomenclatures in Radiation Oncology”. American Institute of Physics; 2018.
• AAPM. AAPM Report No. 275. “Strategies for Effective Physics Plan and Chart Review in Radiation Therapy: Report of AAPM Task Group 275”. American Institute of Physics; 2020.
• AAPM. AAPM Report No. 283. “The report of Task Group 100 of the AAPM: Application of Risk Analysis Methods to Radiation Therapy Quality Management”. American Institute of Physics; 2016.
• AAPM Monographs and Proceedings. https://medicalphysics.org/SimpleCMS.php?content=booklist.php&category=monographs
• National Council on Radiation Protection and Measurements. NCRP Report No. 147 – Structural Shielding Design for Medical X-Ray Imaging Facilities. National Council on Radiation Protection and Measurements; 2005.
• National Council on Radiation Protection and Measurements. NCRP Report No. 151 – Structural Shielding Design and Evaluation for Megavoltage X- and Gamma-Ray Radiotherapy Facilities. National Council on Radiation Protection and Measurements; 2005.
• Bentel GC, Nelson CE, Noell KT. Treatment Planning & Dose Calculation in Radiation Oncology. 4th ed. Pergamon Press; 1989.
• Greene D, Williams PC. Linear Accelerators for Radiation Therapy. 2nd ed. Taylor & Francis; 1997.
• Pawlicki T, Scanderberg DJ, Starkschall G. Hendee's Radiation Therapy Physics. 4th ed. John Wiley & Sons; 2015.
• International Commission on Radiation Units and Measurements. ICRU Report No. 33. “Radiation Quantities & Units”. International Commission on Radiation Units and Measurements; 1980.
• ICRU. ICRU Report No. 50. “Prescribing, Recording and Reporting Photon Beam Therapy”. Oxford University Press; 1993.
• ICRU. ICRU Report No. 62. “Prescribing, Recording and Reporting Photon Beam Therapy (Supplement to ICRU 50)”. Oxford University Press; 1999.
• ICRU. ICRU Report No. 71. “Prescribing, Recording and Reporting Electron Beam Therapy (Supplement to ICRU 50)”. Oxford University Press; 2004.
• ICRU. ICRU Report No. 78. “Prescribing, Recording and Reporting Proton Beam Therapy”. Oxford University Press; 2007.
• ICRU. ICRU Report No. 83. “Prescribing, Recording and Reporting Intensity Modulated Photon Beam Therapy (IMRT)”. Oxford University Press; 2010.
• ICRU. ICRU Report No. 89. “ICRU Report 89, Prescribing, Recording, and Reporting Brachytherapy for Cancer of the Cervix”. Oxford University Press; 2016.
• Johns HE, Cunningham JR. The Physics of Radiology. 4th ed. Charles C Thomas; 1983.
• Karzmark CJ, Nunan CS. Medical Electron Accelerators. McGraw-Hill; 1993.
• Gibbons JP. Khan's The Physics of Radiation Therapy. 6th ed. Walters Kluwer; 2020.
• Klevenhagen SC. Physics and Dosimetry of Therapy Electron Beams. Medical Physics Publishing; 1993.
• McDermott PN, Orton CG. The Physics & Technology of Radiation Therapy. 2nd ed. Medical Physics Publishing; 2018.
• McGinley P. Shielding Techniques for Radiation Oncology Facilities. 2nd ed. Medical Physics Publishing; 2002.
• Metcalfe P, Kron T, Hoban P. The Physics of Radiotherapy X-Rays and Electrons. Medical Physics Publishing; 2007.
• Podgorsak EB. Radiation Oncology Physics: A Handbook for Teachers and Students. IAEA; 2005.
• Rubin P, Bakemeier RF. Clinical Oncology for Medical Students and Physicians: A Multidisciplinary Approach. 5th ed. American Cancer Society; 1978.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Medical Physics Publishing; 1999.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Vol 2. Medical Physics Publishing; 2005.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Vol 3. Medical Physics Publishing; 2013.
• Van Dyk J, ed. The Modern Technology of Radiation Oncology. Vol 4. Medical Physics Publishing; 2020.
• Khan F, Gibbons JP, Sperduto PW. Treatment Planning in Radiation Oncology. Wolters Kluwer; 2016.
• Benedict SH, Schlesinger DJ, Goetsch SJ, Kavanagh BD. Stereotactic Radiosurgery and Stereotactic Body Radiation Therapy. CRC Press; 2015.
• Webb S. Intensity-Modulated Radiation Therapy. Institute of Physics Publishing; 2001.
• Devlin PM, Cormack RA, Holloway CL, Stewart AJ. Brachytherapy: Applications and Techniques. Demos Medical; 2016.

• Madsen MT, Anderson JA, Halama JR, et al. AAPM Task Group 108: PET and PET/CT shielding requirements. Med Phys. 2006;33(1):4-15.
• Bushberg JT, Seibert JA, Leidholt EM Jr, Boone JM. The Essential Physics of Medical Imaging. 4th ed. Lippincott William and Wilkins; 2020.
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All authors meet the following criteria:

• substantial contributions to the conception or design of the work; or the acquisition, analysis, or interpretation of data for the work;
• drafting the work or revising it critically for important intellectual content;
• final approval of the version to be published;
• agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

The authors declare no conflicts of interest.