A Jerusalem district court has upheld a petition by 55 Palestinian doctors seeking to take licensing exams to allow them to practise in Israel—a route into the Israeli medical system that is open to foreign doctors.
about 6 years ago
Commencing the first clinical year is a milestone. Things will now be different as your student career steers straight into the unchartered waters of clinical medicine. New challenges and responsibilities lie ahead and not just in an academic sense. After all this is the awaited moment, the start of the apprenticeship you have so desired and laboured for. It won’t be long before these clinical years like the preclinical years before them, will seem just as distant and insular, so why not make the most of it? The first days hold so much excitation and promise and for many they deliver, however, it would be wise not to be too optimistic. I am afraid your firm head standing abreast the doors in a prophetic splaying of arms is an unlikely sight. In this new clinical environment, it is natural to be a little flummoxed. The quizzical looks of doctors and nurses as you first walk in, a sure sign of your unexpected arrival, is a recurring theme. If the wards are going to be your new hunting ground, proper introductions with the medical team are in order. This might seem like a task of Herculean proportions, particularly in large teaching hospitals. Everyone is busy. Junior doctors scuttling around the ward desks job lists in hand, the registrar probably won’t have noticed you and as luck would have it your consultant firm head is away at a conference. Perseverance during these periods of frustration is a rewarding quality. Winning over the junior doctors with some keenness will help you no end. What I mean to say is that their role in our learning as students extends further than the security of sign-off signatures a week before the end of the rotation. They will give you opportunities. Take them! Although it never feels like it at the time, being a medical student does afford some privileges. The student badge clipped to your new clinic clothes is a license to learn: to embark on undying streaks of false answers, to fail as many skills and clerkings as is required and to do so unabashed. Unfortunately, the junior doctors are not there purely for your benefit, they cannot always spare the time to directly observe a history taking or an examination, instead you must report back. With practice this becomes more of a tick box exercise: gleaning as much information and then reconfiguring it into a structured presentation. However, the performance goes unseen and unheard. I do not need to iterate the inherent dangers of this practice. Possible solutions? Well receiving immediate feedback is more obtainable on GP visits or at outpatient clinics. They provide many opportunities to test your questioning style and bedside manner. Performing under scrutiny recreates OSCE conditions. Due to time pressure and no doubt the diagnostic cogs running overtime, it is fatefully easy to miss emotional cues or derail a conversation in a way which would be deemed insensitive. Often it occurs subconsciously so take full advantage of a GP or a fellow firm mate’s presence when taking a history. Self-directed learning will take on new meaning. The expanse of clinical knowledge has a vertiginous effect. No longer is there a structured timetable of lectures as a guide; for the most part you are alone. Teaching will become a valued commodity, so no matter how sincere the promises, do not rest until the calendars are out and a mutually agreed time is settled. I would not encourage ambuscaded attacks on staff but taking the initiative to arrange dedicated tutorial time with your superiors is best started early. Consigning oneself to the library and ploughing through books might appear the obvious remedy, it has proven effective for the last 2-3 years after all. But unfortunately it can not all be learnt with bookwork. Whether it is taking a psychiatric history, venipuncture or reading a chest X-ray, these are perishable skills and only repeated and refined practice will make them become second nature. Balancing studying with time on the wards is a challenge. Unsurprisingly, after a day spent on your feet, there is wavering incentive to merely open a book. Keeping it varied will prevent staleness taking hold. Attending a different clinic, brushing up on some pathology at a post-mortem or group study sessions adds flavour to the daily routine. During the heated weeks before OSCEs, group study becomes very attractive. While it does cement clinical skills, do not be fooled. Your colleagues tend not to share the same examination findings you would encounter on an oncology ward nor the measured responses of professional patient actors. So ward time is important but little exposure to all this clinical information will be gained by assuming a watchful presence. Attending every ward round, while a laudable achievement, will not secure the knowledge. Senior members of the team operate on another plane. It is a dazzling display of speed whenever a monster list of patients comes gushing out the printer. Before you have even registered each patient’s problem(s), the management plan has been dictated and written down. There is little else to do but feed off scraps of information drawn from the junior doctors on the journey to the next bed. Of course there will be lulls, when the pace falls off and there is ample time to digest a history. Although it is comforting to have the medical notes to check your findings once the round is over, it does diminish any element of mystery. The moment a patient enters the hospital is the best time to cross paths. At this point all the work is before the medical team, your initial guesses might be as good as anyone else’s. Visiting A&E of your own accord or as part of your medical team’s on call rota is well worth the effort. Being handed the initial A&E clerking and gingerly drawing back the curtain incur a chilling sense of responsibility. Embrace it, it will solidify not only clerking skills but also put into practice the explaining of investigations or results as well as treatment options. If you are feeling keen you could present to the consultant on post-take. Experiences like this become etched in your memory because of their proactive approach. You begin to remember conditions associated with patient cases you have seen before rather than their corresponding pages in the Oxford handbook. And there is something about the small thank you by the F1 or perhaps finding your name alongside theirs on the new patient list the following morning, which rekindles your enthusiasm. To be considered part of the medical team is the ideal position and a comforting thought. Good luck. This blog post is a reproduction of an article published in the Medical Student Newspaper, Freshers 2013 issue.
over 6 years ago
The Health Service Journal have announced this week that medical students could be given a license to practice medicine in the NHS as soon as they graduate. What do we know? The proposal comes from Health Education England. Students would qualify by taking an additional exam when applying for the Foundation Programme. The aim is to improve the standard of medics joining the NHS. Another driving force is to reduce the rising number of med students applying for the two-year Foundation Programme (currently the only way for junior doctors to achieve a full license to practice). Last year there were 297 more applicants than places. If approved the plan would require changes to the Medical Act. Statement from the BMA Dr Andrew Collier, Co-Chair of the BMA’s Junior Doctor Committee said: “We do not feel the case has yet been made for a wholesale change in foundation programme selection process, especially as the system was significantly overhauled and implemented only one year ago. There is little evidence that another new national exam over and above current medical school assessment methods will add any benefit either for graduating students or the NHS as a whole. It is also unlikely to solve the ongoing oversubscription to the foundation programme which will only be addressed by well thought out workforce planning.” Will it work? This proposal has certainly come as a surprise to me so soon after recent changes to the Foundation Programme selection process. I would love to know what you think about it. Do you agree with Dr Collier’s statement? If the plan goes ahead do you think it will be effective in achieving the desired outcomes? Please post your comments and thoughts. Nicole Read more: http://www.hsj.co.uk/news/exclusive-medical-students-face-new-nhs-entry-exam/5066640.article#.UrbyS2RdVaE
over 6 years ago
I'm thinking of applying to take the US Medical Licensing Exam (USMLE). Does anyone who is preparing for, or who has taken the exam, have any advice for prospective entrants regarding: The best point during undergraduate/postgraduate training to take the exams Helpful resources when preparing for the exams Any other useful advice or top tips?
over 7 years ago
What is Problem Based Learning? During my time at medical school, I enjoyed (at times) a curriculum delivered through the traditional model. As the name suggests, this is an approach experienced by the majority of doctors to date. The traditional model was first implemented by the American Medical College Association and American Academy of Medicine in 1894 (Barr, 2010) and has been used by the majority of medical schools. It traditionally consists of didactic lectures in the initial years covering the basic sciences followed by clinical years, where students learn clinical medicine while attending hospital placements. Is It Better? A few years after my graduation I found myself teaching at a university which had fully adopted the use of problem based learning (PBL) in the delivery of their curriculum. PBL is a philosophy of teaching that has increasingly been used in medical education over the past 40 years. It has rapidly been replaced or supplemented in medical education as opposed to the traditional model. PBL seeks to promote a more integrated and active approach to learning right from the first year with less reliance on didactic lectures. Having been involved in these two different approaches to medical education, I was interested to explore what the evidence was for and against each. For the purposes of this blog, I have looked at four specific areas. These include student attitudes, academic achievement, the academic process of learning and clinical functioning and skills. Student Attitudes Student attitudes to PBL have been highly featured in studies and many show that there is a clear favourability towards this philosophy of teaching. Blumberg and Eckenfel (1988) found that students in a problem based preclinical curriculum rated this three times higher than those in the a traditional group in terms of what they expect to experience, what they would like, and what they actually experienced. Heale et al (1988) found physicians in the problem-solving sessions rated a Continuing Medical Education short course higher compared to others who attended traditional lectures and large-group sessions. Vernon and Black (1993) performed a Meta analysis on 12 studies that looked at attitudes and towards PBL and found PBL was favored in some way by all studies. PBL appears to be preferred by the majority of students at a range of academic levels. However, Trappler (2006) found that converting a conventional curriculum to a problem based learning model for part of a psychopathology course did not show complete favourability. Students preferred the conventional lectures given by experts, rather than PBL groups run by mentors and not experts. They did however show preference towards PBL small group sessions run by experts Academic Achievement Academic achievement is an important factor to assess. Vernon and Blake (1993) compared a number of studies and found that those, which could be compared, showed a significant trend favouring traditional teaching methods. However, it was felt this might not be reliable. When looking at the heterogeneity of the studies there was significant variation that could not be accounted for by chance alone. Interestingly, they found that there was significant geographical variation across the United States such that New Mexico showed consistently negative effects and Michigan State showed consistently positive. Other studies have shown that the traditional method may show a slightly better outcome when assessing academic achievement. Schmidt et al (1987) looked at the same progress test taken among students in six different Universities in the Netherlands and found that those taught by a traditional approach showed slightly better outcomes. Baca et al (1990) compared performances of medical students in two separate tracks, one PBL the other a traditional model. Baca et al found that PBL students scored slightly lower in the National Board of Medical Examiners (NBME) examinations. Dochy et al (2003) conducted a meta analysis comparing 43 studies and found that when considering the effect of PBL on the knowledge of students the combined effect size is slightly negative. The academic process of learning It is important in medical education to enable people to continue life long learning, to overcome problems and fill in knowledge gaps. Coles (1990) and Entwistle (1983) found that PBL students would place more emphasis on understanding and meaning compared to just rote learning, seen more in those taught by a traditional approach. Students on a PBL course also place more focus on using resources such as the library and online sources rather than those taught in a traditional approach (Rankin, 1992). Students taught by a traditional model place more emphasis on the resources supplied by the faculty itself. It has also been shown that students who learn through a process of problem solving, are more likely to use this spontaneously to solve new problems in the future compared with those taught in a traditional way (Bransford et al, 1989). Clinical functioning and skills Clinical competence is an important aspect in medical education and has been measured in studies comparing PBL and traditional methods. The traditional model focuses acquisition of clinical competence in the final years of a program with hospital placements. In a PBL course it may be more integrated early on. There are however, only a few studies that look at clinical competence gained in undergraduate PBL courses. Vernon and Blake (1993) compared some of these studies and found that students obtained better clinical functioning in a PBL setting compared to a traditional approach. This was statistically significant, however there was still significant heterogeneity amongst studies and for conclusive results to be made 110 studies would have to be compared, rather that the 16 samples they were able to use. They also found that in contrast to the NBME I giving better results in the traditional model, PBL students score slightly higher in NBME II and federation licensing examination which related more on clinical functioning than basic sciences. On reflection, this evidence has indicated to me that PBL is a very valuable approach and it has a number of benefits. The traditional model in which I was taught has provided a good level of academic education. However, it may not have supported me as well as a PBL course in other areas of medical education such as academic process, clinical functioning and satisfaction. On reflection and current recommendations are for a hybridisation of the PBL and traditional approach to be used (Albanese, 2010) and I would support this view in light of the evidence. References Baca, E., Mennin, S. P., Kaufman, A., and Moore-West, M. A Comparison between a Problem-Based, Community Orientated track and Traditional track Within One Medical school. In Innovation in Medical Education; An Evaluation of Its Present Status. New York: Springer publishing Barr D. (2010) Revolution or evolution? Putting the Flexner Report in context. Medical Education; 45: 17–22 Blumberg P, Eckenfels E. (1988) A comparison of student satisfaction with their preclinical environment in a traditional and a problem based curriculum. Research in Medical Education: Proceedings of the Twenty-Seventh Annual Conference, pp. 60- 65 Bransford, J. D., Franks, J. J., Vye, N. J., & Sherwood, R. D. (1989). New Approaches to Instruction: Because Wisdom Can't Be Told. In S. Vosiadou & A. Ortony (Eds.), Similarity and Analogical Reasoning (pp. 470 297). New York: Cambridge University Press. Coles CR. (1990) Evaluating the effects curricula have on student learning: toward a more competent theory for medical education. In: Innovation in medical education: an evaluation of its present status. New York: Springer publishing; 1990;76-93. Dochy F., Segersb M., Van den Bosscheb P., Gijbelsb D., (2003) Effects of problem-based learning: a meta-analysis. Learning and Instruction. 13:5, 533-568 Entwistle NJ, Ramsden P. Understanding student learning. London: Croom Helm; 1983 Heale J, Davis D, Norman G, Woodward C, Neufeld V, Dodd P. (1988) A randomized controlled trial assessing the impact of problem-based versus didactic teaching methods in CME. Research in Medical Education.;27:72-7. Trappler B., (2006) Integrated problem-based learning in the neuroscience curriculum - the SUNY Downstate experience. BMC Medical Education 6: 47. Rankin JA. Problem-based medical education: effect on library use. Bull Med Libr Assoc 1992;80:36-43. Schmidt, H G; Dauphinee, W D; Patel, V L (1987) Comparing the effects of problem-based and conventional curricula in an international sample Journal of Medical Education. 62(4): 305-15 Vernon D. T., Blake R. L., (1993) Does Problem-based learning work? A meta-analysis of evaluated research. Academic Medicine.
Dr Alastair Buick
over 7 years ago
Introduction This post describe the creation of a Stroke Summary video. The aim of this project was to assess the attitudes of medical students towards the use of video animation in medical education. An educational tutorial was produced outlining the basic principles of stroke. This aimed to provide a summary of different aspects relating to stroke, outlined in the Bristol University curriculum. This intended to be a short, concise animation covering stroke presentation, definition and recognition, with an overview of the blood supply to the brain and the classification of stroke presentation used in clinical practice. This was followed by some key facts and a summary of different management stages. After the video animation was produced an assessment of student’s attitudes using an online questionnaire was undertaken. This consisted of ten short questions and an open text feedback for additional comments. The video was then edited with reference to feedback given by students and the results analysed. This report will outline relevant research and project work that lead to this assignment being undertaken. A description of the method followed to generate the video animation and to collect feedback on students will be outlined followed by analysis of results. This will then be discussed in relation to previous work and research. Background There are a number of reasons this project has been undertaken. On a personal level, I have a long-standing interest in teaching and medical education. As part of a previous project I created a series of audio tutorials in cardiovascular medicine and assessed student attitudes to audio learning. The findings of this report showed that a large number of students found these audio tutorials useful and would like more of these available to supplement their learning. One of the questions given to students at this time assessed how useful they found different types of educational material. This project showed students reporting audio tutorials more useful than previously thought, while also reporting that they were not readily available. Although a video tutorial was not provided to them at this time, feedback questions assessed attitudes to video tutorials as a learning resource. Students reported low availability and felt they would be more useful than audio tutorials. Some results from this project are shown in figure 1. Figure 1. Results from previous research by Buick (2007), showing attitudes of students towards different learning tutorials. The majority of students report audio tutorials to be ‘quite useful’ or ‘very useful’. Video tutorials are thought by students to be more useful that audio tutorials, however there is a large proportion that do not have access to these learning resources. As a number of students reported an inability to access to video tutorials, it was thought that creating a video animation tutorial followed by assessing students attitudes would be a useful follow up project. If this is found to be a useful resource, other students may generate video tutorials in the future. Therefore student feedback also assessed attitudes towards authenticity, relating to who generates the tutorial and whether they find the ability to feedback a useful tool. Medical education is widely researched globally, although it is not often a consideration for those studying medicine. Those involved in teaching and educating future doctors have looked at different methods of passing on knowledge. A high quality medical education given to future healthcare professionals is important. It is widely accepted that a better knowledge results in better care for patients and education is at the centre of any healthcare system. This is reflected in the cost of educating medical students and training doctors in the UK. In the 1997 it was reported by the Department of Health that estimates of 200 million pounds would be spent per year for an increase in 1000 medical students being trained in the UK. This suggests that the cost of training a medical student is in the region of £200,0001. Medical education in the UK is split in two halves, with undergraduate and postgraduate training. The Department of Health has recently invested millions of pounds into the development of online tutorials for postgraduate training posts in a number of different specialities. Justification for is given by reducing the cost of training through the use of standardised online tutorials. This will be a more cost effective method than the standard in hospital teaching. This approach has not been undertaken for undergraduate medical education. Universities are seen as primarily responsible for undergraduate training. Many of these institutions have used the Internet to aid teaching and have produced video tutorials. However, as reflected in the previous project (Buick, 2007), resources are often limited and students do not feel they have ready access to these educational tutorials. The benefits of different types of learning resource have been researched. These include online audio downloads (Spickard et al, 2004), practice exam questions and interactive tutorials (Hudsen, 2004). Research showing the benefit of video was shown by Balslev et al (2005) comparing video and written text while teaching a patient case. Balsley et al (2005) found those who learnt using a video presentation rather than those given written text showed a significant increase in data exploration, theory evaluation and exploration. However, there is little research looking specifically at video animation for explaining conditions. Animation software is now available on personal computers and is also possible using Microsoft PowerPointTM, which is the most widely used presentation software. It is clear that recent trends show training can benefit from this type of learning resource. Generation of high quality video tutorials can help students learn while reducing the cost of training. It is for this reason that more material is likely to become available, either from funded production supported by external organisations or by the trainers and trainees themselves who have technology able to produce material such as this on their home computer. Ethical and Legal Issues During the development of this video some ethical and legal issues arose that had to be addressed before a final video could be made. When considering what imagery would be used in the video, I wanted to include pictures of clinical signs relevant to the audio narration. However, taking images from the Internet without prior consent was not thought to be ethical and therefore clinical signs were displayed graphically through drawings and diagrams. Plagiarism and copyright were some of the legal issues surrounding the presentation of medical information. Narrated information was generated using a number of information sources, none of which were exclusively quoted. Therefore an end reference list was generated showing all supporting information sources. Images used in the animation were either self generated or taken from sources such as Wikipedia.org. This resource supplies images under a free software license such as GNU general public license2. This allows anyone to freely use and edit images while referencing the original source. Skills Needed To Develop This Video Animation To generate the video a number I had to develop a number of new skills. Unlike previous work that had been undertaken this media was generated using animation software. To use this effectively I had to research the different functions that were available. To do this I combined reading books aimed to teach beginners such as Macromedia Flash 8 for Dummies (Ellen Finkelstein and Gurdy Leete, 2006) and online sources such as www.learnflash.com . To generate voice narration, another program was used that allowed editing and splicing of audio tracks. This was then split up into a number of narrated sections and added to the animation. Method Script To produce the tutorial the first stage was to construct a script for narration. This involved outlining the areas to be covered. The main headings used were: Stroke definition This gave a clinical definition and a lay person recognition mnemonic called FAST which is used to help members of the general public recognise stroke. Pathophysiology This covered blood supply to the brain. This combined diagrams of the circle of Willis, with images of the brain. Arterial blood supply were then displayed over the brain images while relating this to the arterial vessels leaving the circle of Willis Classification Students at Bristol university are asked to understand the Oxford / Bamford classification. This was covered in detail with explanations of clinical signs that may be seen and graphical representation of these. Prevalence This section covered prevalence, national impact and cost of stroke in the UK. Management In this section management was split up it to immediate management, medical management, in hospital care and some of the procedures considered for different cases. Risk factors for stroke and research into this was also written up and narrated. However at a later stage this was not included due to time constraints and video length. Narration An audio narration was generated using software called ‘Garage Band’ which allows audio tracks to be recorded and edited. The narration was exported in 45 sections so that this could then be added to the animation at relevant points. Animation The animation was made using Adobe Flash. This software is used for making websites and animations used for Internet adverts. It has the facility to export as a ‘flash video format’, which can then be played using a media player online. This software generates animation by allowing objects to be drawn on a stage and moved around using command lines and tools. This was used as it has the ability to animate objects and add audio narration. It also is designed for exporting animations to the Internet allowing the material to be accessed by a large number of people. Feedback A short questionnaire was generated which consisted of ten questions and placed online using a survey collection website (www.surveymonkey.com). Students were directed to the feedback questionnaire and allowed to submit this anonymously. Adapting the tutorial Some feedback constructively suggested changes that could be made. The video was updated after some concern about the speed of narration and that some of the narrative sections seemed to overlap. Analysis and Report The results of the feedback were then collected and displayed in a table. This was then added to the report and discussed with reference to research and previous project work. Results Students were allowed to access to the video animation through the Internet. After uploading the video an email was sent to students studying COMP2 at Bristol University. These students are required to know about aspects of stroke covered in this tutorial to pass this section of the course. The email notified them of the options to view the tutorial and how to give feedback. In total 30 students completed the feedback questionnaire and out of these 4 students provided optional written feedback. The results to the questions given were generally very positive. The majority of students showed a strong preference to video animations as a useful tool in medical education. The results are displayed in Table 1 below. TABLE 1 shows the ten question asked of the students and to what extent they agreed with each statement. Results are given in the percentage of students who chose the relevant category. Written Feedback Four written comments were made: "Really useful presentation!! Would be much better if someone proof read the whole thing as there are some spelling mistakes; also if the pauses between facts were longer it would be more easier to take in some facts. Overall, really nicely done!!" "Some of speech went too quickly, but good overall" "Very clearly written with excellent use of images to match the text and commentary!" "The Video was excellent." Discussion Student attitudes to this video tutorial were very positive. This was in contrast to the attitudes previously shown in the audio tutorial project (Buick, 2007) where video tutorials were not thought to be a useful resource. These results support recent developments in the generation of online video training for doctors by the Department of Health and previous research by Balsley et al (2005). Question one showed that the majority of students strongly agreed that the stroke video would be a useful resource. Questions two, three and four aimed to establish what aspects of a disease were best outlined using a video animation. Results showed that students agree or strongly agreed that defining the condition, pathophysiology and management were all well explained in this format. Interestingly, a large majority of students (70%) felt pathophysiology was best represented kinaesthetically. This may be due to the visual aspect that can be associated with pathophysiology. Disease processes are often represented using diagrams in textbooks with text explaining the disease process. Using computer technology it is possible to turn the text into audio narration and allow the user to view dynamic diagrams. In this way, students can better conceptualise the disease process, facilitating a more complete understanding of disease and its clinical manifestations. Question five aimed to highlight the benefit of visual stimulation as well as audio narration as a positive learning method. All students agreed or strongly agreed that the combination of these two aspects was beneficial. Question six showed a very strong response from students wanting access to more video tutorials, with 70% of students strongly agreeing to this statement. It is often the case that students take part in generating teaching material, and some students may be concerned that this material is inaccurate. However, many students do not think that this is a significant problem. This is reflected by the spread of student’s opinion seen in question 7, where there was no clear consensus of opinion. It may be that as students learn from a number of different resources, that any inaccuracies will be revealed and perhaps stimulate a better understanding through the process of verifying correct answers and practicing evidence based medicine. Question nine and ten show that most students value resources that allow sharing of educational material and feel they could help others learn. They would also value the option to feedback on this material. The written feedback showed positive responses from students. However there was feedback on some aspects of the video that they felt could be changed. The narration was delivered quickly with few gaps between statements to keep the tutorial short and concise, however this was thought to be distracting and made it less easy to follow. Following this feedback the narration was changed and placed back on the Internet for others to review. Further research and investigation could include the generation of a larger resource of video animations. My research has suggested that using animation to cover pathophysiology may be most beneficial. The software used to make this video also allows for the incorporation of interactive elements. The video produced in this project or other videos could have online menus, allowing users to select which part of the tutorial they wish to view rather than having to watch the whole animation, or they include interactive questions. Reflections Strength and weaknesses Strengths of this project include its unique approach to medical education. There have been few animated videos produced for undergraduate medical students that use this advanced software. This software is used by professional web developers but can be used effectively by students and doctors for educational purposes to produce video animation and interactive tutorials. For these reasons, I passionately believe that this technology could be used to revolutionise the way students learn medicine. If done effectively this could provide a more cost effective and engaging learning experience. This will ultimately benefit patients and doctors alike. This material can be place online allowing remote access. This is increasingly important for medical students studying on placements who are often learning away from the university setting. Weaknesses of this project include that of the work intensity of generating animated video. It is estimated that it takes around 6 to 9 hours to produce a minute of animated video. This does not include the research and recording of narration. The total sum of time to generate material and the additional skills needed to use the software makes generation of larger numbers of videos not possible by a small community of learners such as a university. Although it was done in this case, it is difficult to edit the material after it has been created. This may mean that material will become inaccurate when new advances occur. The feedback sample collected was opportunistic and the response rate was low. These factors may bias the results as only a subsection of opinions may have been obtained. These opinions may not be representative of the population studied or generalisable to them. It was difficult obtaining a professional medical opinion about the video in the time that I was allocated. However this has been organised for a later time. Knowledge and skills gained During this project I was able to learn about stroke its presentation, classification, management and risk factors. I read texts, which summarised stroke and research into risk factors and management of stroke. The challenge of usefully condensing a subject into a short educational tutorial was a challenging one. I feel I improved my skills of summarising information effectively. I gained knowledge of some of the challenges of undertaking a project such as this. One of the largest challenges included how long it took to produce the animation. In the future I will be aware of these difficulties and allow for time to gather information and generate the material. I also learnt the benefit of gaining feedback and allowing for adaption to this. It took more time to respond to feedback but this resulted in a better product that other students can use. I also reflected on the impact of stroke itself. Stroke has a major impact on patients, health care and carers. Much can be done in the recognition classification and management. A better understanding benefits all areas and I have gained a better knowledge and the importance of helping others gain a good understanding of stroke. I learned how to generate a video animation for the use of teaching in medicine and combine this with audio presentation. I learned how long it can take to generate material like this and the skill of organising my time effectively to manage a project. I can use this skill in the future to produce more educational material to help teach during my medical career. I also gained skills in learning how to place material on the Internet for others to access and will also use this in the future. Conclusions Previously evidence has shown the use of videos in medical education to be beneficial. It has normally been used to demonstrate clinical examination and procedures this study suggest there is a place for explanation of pathophysiology and disease summaries. However, there has been little research in to its use for graphically representing condition summaries. Computer technology now allows people to generate animation on their personal computer. It is possible that over time more students and doctors will start producing innovative visual and audio teaching material. This project indicates that this would be well received by students. References Planning the Medical Workforce: Medical Workforce Standing Advisory Committee: Third Report December. 1997 Page 40. The GNU project launched in 1984. Balslev T, de Grave W S, Muijtjens A M and Scherpbier A J (2005) Comparison of text and video cases in a postgraduate problem-based learning format Medical Education; 39: 1086–1092 Buick (2007) Year 3 External SSC. Bristol University Medical School. Spickard A, Smithers J, Cordray D, Gigante J, Wofford J L. (2004) A randomised trial of an online lecture with and without audio; Medical Education 38 (7), 787–790. Hudson J. N., (2004) Computer-aided learning in the real world of medical education: does the quality of interaction with the computer affect student learning? Medical Education 38 (8), 887–895. Ellen Finkelstein and Gurdy Leete, (2006) Macromedia Flash 8 for Dummies. Wiley publishing Inc. ISBN 0764596918
Dr Alastair Buick
over 10 years ago