ABSTRACT
INTRODUCTION: Surgery represents a major source of carbon emissions, with numerous initiatives promoting more sustainable practices. Healthcare innovation and the development of a digitally capable workforce are fundamental in leveraging technologies to tackle challenges, including sustainability in surgery. METHODS: A surgical hackathon was organised with three major themes: (1) how to make surgery greener, (2) the future of plastic surgery in 10 years, and (3) improving healthcare outcomes using machine learning. Lectures were given on sustainability and innovation using the problem, innovation, market size, strategy and team (PIMST) framework to support their presentations, as well as technological support to translate ideas into simulations or minimum viable products. Pre- and post-event questionnaires were circulated to participants. RESULTS: Most attendees were medical students (65%), although doctors and engineers were also present. There was a significant increase in delegates' confidence in approaching innovation in surgery (+20%, p < 0.001). Reducing waste packaging (70%), promoting recyclable material usage (56%) and the social media dimension of public perceptions towards plastic surgery (40%) were reported as the most important issues arising from the hackathon. The top three prizes went to initiatives promoting an artificial intelligence-enhanced operative pathway, instrument sterilisation and an educational platform to teach students research and innovation skills. CONCLUSIONS: Surgical hackathons can result in significant improvements in confidence in approaching innovation, as well as raising awareness of important healthcare challenges. Future innovation events may build on this to continue to empower the future workforce to leverage technologies to tackle healthcare challenges such as sustainability.
ABSTRACT
BACKGROUND: Currently, safe practice in the UK esthetics industry is largely reliant on self-regulatory bodies. If these bodies do not maintain high standards of safety guidelines and properly accredit practitioners, patient safety may be at risk. To our knowledge, no studies have addressed cosmetic self-regulatory bodies and their websites on Google, the most commonly used information source. This study aimed to map self-regulatory bodies on Google and evaluate their roles in the current UK esthetics industry. METHOD: We conducted a systematic search of Google Search results using eight search terms. The first 100 search results were screened against our eligibility criteria. We searched each website of a self-regulatory body for their requirements to join registers, membership fees, and features listed on the UK government's criteria for an effective self-regulatory body. RESULTS: We identified 22 self-regulating bodies for the UK esthetics industry. Only 15% of registers required an in-person assessment of cosmetic skills to qualify for membership. Of the self-regulatory bodies, 65% did not set clear standards and guidelines for practice. No qualifications were required by 14% of surgical and 31% of non-surgical bodies. The mean membership fee was £331. CONCLUSION: This study uncovered important information about the self-regulation of the esthetics industry in the UK. A significant majority of self-regulatory bodies did not meet best practices, potentially putting patients at risk. We recommend further studies screening a higher number of pages in a Google Search to scope all other existing self-regulatory bodies, due to the creation of Google "filter bubbles."
Subject(s)
Patient Safety , Humans , United KingdomABSTRACT
High strength steels are becoming more important than ever before for automotive applications to reduce the weight of automobiles and to ensure the safety of passengers. Since increased strength usually results in degraded formability, however, cold forming of high strength steels into final shapes remains a challenge to both automotive manufacturers and suppliers. Here we report novel alloy and processing design concepts that can impart high strength to cold-formable steels, which deviates from the traditional approach of improving the formability of high strength steels. Such designed steel subjected to a designed processing route shows an excellent combination of formability and strength as well as crashworthiness, which is crucial for the safety of passengers in the automobiles. The alloy and processing design concepts used in the present study are based on the utilization of thermally induced austenite to martensite transformation, which imparts high strength to cold-formable austenite by cryogenic treatment.
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BACKGROUND: ENT is highly under-represented in the saturated UK medical school curriculum, comprising less than 1 per cent of the curriculum. A 1-day course was implemented in order to raise awareness of ENT among medical students, educate them in the specialty and teach a basic skill. METHODS: The skills day comprised lectures by consultants followed by a consultant-led workshop teaching tracheostomy. Pre- and post-course questionnaires assessed perceptions of ENT, confidence performing tracheostomy and interest in ENT as a career. RESULTS: Perceptions of ENT as a specialty were improved by up to 80 per cent (p < 0.01). There was improved understanding of and confidence in performing tracheostomies. Interest in a career in ENT was increased by 77 per cent (p < 0.01). CONCLUSION: A 1-day course run by a student body can be a powerful adjunct to the medical school curriculum, in terms of educating undergraduates in ENT and inspiring the pursuit of ENT as a career.
Subject(s)
Otolaryngology/education , Students, Medical/psychology , Tracheostomy/education , Career Choice , Clinical Competence , Competency-Based Education , Female , Humans , Male , Schools, Medical , Surveys and QuestionnairesABSTRACT
We introduce a novel transformation-induced plasticity mechanism, i.e., a martensitic transformation from fcc phase to bcc phase, in medium-entropy alloys (MEAs). A VCrFeCoNi MEA system is designed by thermodynamic calculations in consideration of phase stability between bcc and fcc phases. The resultantly formed bcc martensite favorably contributes to the transformation-induced plasticity, thereby leading to a significant enhancement in both strength and ductility as well as strain hardening. We reveal the microstructural evolutions according to the Co-Ni balance and their contributions to a mechanical response. The Co-Ni balance plays a leading role in phase stability and consequently tunes the cryogenic-temperature strength-ductility balance. The main difference from recently-reported metastable high-entropy dual-phase alloys is the formation of bcc martensite as a daughter phase, which shows significant effects on strain hardening. The hcp phase in the present MEA mostly acts as a nucleation site for the bcc martensite. Our findings demonstrate that the fcc to bcc transformation can be an attractive route to a new MEA design strategy for improving cryogenic strength-ductility.
ABSTRACT
Although magnesium alloys, as the lightest structural alloys, offer significant potential for automotive applications, their applications remain limited due to their poor formability at room temperature. Since the strategies used for improving formability usually result in a degradation of strength, there are no high strength magnesium alloys showing good formability. Here we report an alloy design concept that can simultaneously provide high strength and good formability. Such designed alloy when subjected to an appropriate processing technique shows a combination of strength and formability that surpasses those of the existing magnesium alloys reported so far. The alloy design concept used in the present study is based on the utilization of alloying elements that can induce precipitation, as well as maximize the segregation of other texture-controlling alloying elements. Such developed alloy is expected to broaden the application of Mg alloy sheets, which are now starting to gain acceptance by automotive industries.
