What does the literature say about preceptorship and mentorship in radiography: A scoping review of the current research and identified knowledge gaps.

OBJECTIVES: Effective transition into radiography practice for newly qualified radiographers (NQR's), radiographers returning to practice after career breaks, and internationally trained radiographers requires support inclusive of preceptorship and mentorship. The purpose of this scoping review is to evaluate the literature pertaining to preceptorship and mentorship support in radiography to identify knowledge gaps. This is timely in view of the health and care professions council (HCPC) recently published preceptorship guidance. KEY FINDINGS: A scoping review methodology underpinned by Arksey and O'Malley framework was undertaken, which employed a systematic search using combined keywords and Medical Subject Heading terms (MeSH) related to preceptorship and mentorship, of electronic databases: CINAHL, Pubmed, Embase, Scopus and Google scholar. A predetermined inclusion and exclusion criteria were used to screen by three independent reviewers, the titles, abstract and full text of articles using Covidence software (www.covidence.org). 10 articles in the English language were selected for the final review. 1574 articles were retrieved and assessed for eligibility, and 10 articles published between 2006 and 2022 met the inclusion criteria. Most of the research was conducted in the United Kingdom and only one study was published in Australia. The studies mainly focused on experiences of NQR, and experienced radiographers' perspectives on preceptorship and mentorship in diagnostic and radiotherapy radiography. It was established from the studies that there is variation in approaches to the transition process in terms of types of programmes, duration, and quality. Self-reported increase in confidence and competence was noted as a central objective, and barriers to implementation were identified to include lack of awareness and accessibility to available programmes, lack of clarity on aims and intended benefits, and lack of employer support pertaining to protected time. CONCLUSION: The paucity of research renders current preceptorship and mentorship practices in radiography inadequate for effective transition of different radiography groups into their role. Further research is required to evaluate the models of preceptorship and mentorship, their impact and intended outcomes on radiography practice. IMPLICATIONS FOR PRACTICE: The identification of knowledge gaps in this area can support employers and researchers in the development of effective models of preceptorships and mentorship which can be evaluated for implementation for specific radiography groups.

An exploration of communication skills development for student diagnostic radiographers using simulation-based training with a standardised patient: UK-based focus-group study.

INTRODUCTION: Communication is an essential skill for all healthcare professionals but is particularly challenging for diagnostic radiographers since their role involves conveying extensive information within a relatively short amount of time. One method to develop communication skills in radiography is through simulation-based training using high fidelity simulation activities. The use of video recording for reflection and debriefing are also important elements that can be utilised to enhance learning. The aim of this project was to explore student radiographers' experiences of a simulation-based activity utilising a standardised patient designed to aid development of communication skills. METHODS: Fifty-two undergraduate 3rd year diagnostic radiography students at a single Higher Education Institution undertook a simulation roleplay exercise with an expert by experience (EBE) who acted in an anxious manner in order to challenge the student's communication skills following the simulation, students received a debrief session where detailed feedback was provided from the EBE and an academic. Students were also able to watch their video of the simulation and reflect. Students were invited to participate in a focus group to discuss their experience and the learning they had developed and 12 students participated. Transcribed material from the focus groups was thematically analysed to deduce themes of learning developed and ways to improve for future simulations. FINDINGS: Six main themes were identified from the thematic analysis of the transcripts from 12 diagnostic radiography students. These were patient care, radiographer's role and responsibilities, personal development, feelings, fidelity, and pedagogy. The themes represented the key learning points expressed by students and also aspects of the simulation which could be improved. Overall, the simulation provided a positive learning experience for the students. Having a video recording of the scenario was regarded as beneficial to enable a depth of reflection on non-verbal communication skills, which would be beneficial in future simulation scenarios. Students were aware that even though they used appropriate language their overall manner affected the interaction with the expert by experience more significantly. Students also considered methods to improve their communication if they encountered a similar patient interaction in their future practice. CONCLUSION: There is great potential for simulation-based training in developing communication skills for diagnostic radiography students. EBEs are a vital addition to simulation and educational activities in Higher Education Institutions and should be involved with the design of simulation activities also, as they can bring unique patient insight.

Radiographers' self-perceived competencies after attending postgraduate courses in CT and MRI.

INTRODUCTION: Postgraduate education in computed tomography (CT) and magnetic resonance imaging (MRI) varies globally. Multiple factors affect the development of associated core skills and competencies for these specialist roles. Previous research has highlighted that different teaching standards and methods may influence radiographers' confidence and competencies. Nonetheless, there is limited knowledge of skill development and capabilities in post-registration roles. Hence, the aim of this research was to explore radiographers' self-perceived competencies before, during and after successful completion of postgraduate study. METHODS: Radiographers enrolled on the CT and MRI courses voluntarily completed questionnaires at three time points. As part of the last survey, questions were added to evaluate their perceptions of the courses' impact on their clinical and professional practice. Descriptive statistics, Wilcoxon matched pairs signed rank and Friedman tests, were performed to analyse results across the different time points. RESULTS: 53 students completed the baseline survey, with initial perceived areas of weakness being lack of knowledge relating to CT or MR technology, cross-sectional anatomy and pathology. Follow up surveys, highlighted a significant increase in self-described competence in technical knowledge, literature appraisal and image viewing skills. As a result of completing the course, students described favourable changes to their departmental practices and their own continuing professional development (CPD). Challenges detailed included but not limited to lack of study time provided by employers, and the demands of balancing studies and work commitments. CONCLUSION: Postgraduate education has value and positively impacts radiographers and their clinical departments. The courses enabled the radiographers, including those experienced in CT and or MRI to develop skills they could translate into clinical practice, thereby contributing towards service delivery. IMPLICATIONS FOR PRACTICE: Post graduate education has the potential to enhance self-perceived competency in aspects of CT and MRI practice.

Computer based simulation in CT and MRI radiography education: Current role and future opportunities.

OBJECTIVE: The use of Computer-based simulation (CBS), a form of simulation which utilises digital and web based platforms, is widely acknowledged in healthcare education. This literature review explores the current evidence relating to CBS activities in supporting radiographer education in CT and MRI. KEY FINDINGS: Journal articles published between 2010 and 2020 were reviewed (n = 663). The content was evaluated and summarised with the following headings; current utility, overview of CBS types, knowledge acquisition and evaluation, and student perspective. CBS utility in CT and MRI radiography education is limited. Its current use is for pre-registration education, and the interfaces used vary in design but are predominantly used as a preclinical learning tool to support the training of geometric scan planning, image acquisition and reconstruction, and associated technical skills. CBS was positively acknowledged by student radiographers; based on its inherent flexibility, self-paced learning and the ability to practice in a safe environment. Nonetheless, the educational validation of CBS in CT and MRI education pertaining to knowledge and skill acquisition has not been fully assessed through rigorous academic assessments and metrics. CONCLUSION: The current use of CBS in CT and MRI education is limited. The development of software programmes with functionality and capability that correlates with current clinical practice is imperative; and to enable more research in CBS utility to be undertaken to establish the efficacy of this pedagogical approach. IMPLICATIONS FOR PRACTICE: Due to limited placement opportunities, the use of simulation is increasing and evolving; in line with the approach to design and deliver high quality Simulation Based Education (SBE) in Diagnostic Radiography education. The continued development, utility and evaluation of CBS interfaces to support student radiographers at pre and post registration level is therefore essential.