Clinical photography is a valuable tool for physicians. Smartphones, as well as other devices supporting network connectivity, offer a convenient, efficient method to take and share images. However, due to the private nature of the information contained in clinical photographs there are concerns as to the appropriate storage, dissemination, and documentation of clinical images. Confidentiality of image data must be considered and the dissemination of these images onto servers must respect the privacy and rights of the patient. Importantly, patient information should be considered as any information deriving from a patient, and the concepts outlined therefore apply to any media that can be collected on, or transmitted with, a smart-device.
Clinical photography can aid in documenting form and function, in tracking conditions and wound healing, in planning surgical operations, and in clinical decision-making. Additionally, clinical photographs can provide physicians with a valuable tool for patient communication and education. Due to the convenience of this type of technology it is not appropriate to expect physicians to forego their use in providing their patients with the best care available.
The technology and software required for secure transfer, communication, and storage of clinical media is presently available, but many devices have non-secure storage/dissemination options enabled and lack user-control for permanently deleting digital files. In addition, data uploaded onto server systems commonly cross legal jurisdictions. Many physicians are not comfortable with the practice, citing security, privacy, and confidentiality concerns as well as uncertainty in regards to regional regulations governing this practice.1 Due to concern for patient privacy and confidentiality it is therefore incredibly important to limit the unsecure or undocumented acquisition or dissemination of clinical photographs.
To assess the current state of this topic, Heyns et al. have reviewed the accessibility and completeness of provincial and territorial medical regulatory college guidelines.2 Categories identified as vital and explored in this review included: Consent; Storage; Retention; Audit; Transmission; and Breach. While each regulatory body has addressed limited aspects of the overall issue, the authors found a general lack of available information and call for a unified document outlining pertinent instructions for conducting clinical photography using a smartphone and the electronic transmission of patient information.2
The discussion of this topic will need to be ongoing and it is important that physicians are aware of applicable regulations, both at the federal and provincial levels, and how these regulations may impact the use of personal devices. The best practices supported here aim to provide physicians and healthcare providers with an understanding of the scope and gravity of the current environment, as well as the information needed to ensure patient privacy and confidentiality is assessed and protected while physicians utilize accessible clinical photography to advance patient care. Importantly, this document only focusses on medical use (clinical, academic, and educational) of clinical photography and, while discussing many core concepts of patient privacy and confidentiality of information, should not be perceived as a complete or binding framework. Additionally, it is recommended that physicians understand the core competencies of clinical photography, which are not described here.
The Canadian Medical Association (CMA) suggests that the following recommendations be implemented, as thoroughly as possible, to best align with the CMA policy on the Principles for the Protection of Patient Privacy (CMA Policy PD2018-02). These key recommendations represent a non-exhaustive set of best practices - physicians should seek additional information as needed to gain a thorough understanding and to stay current in this rapidly changing field.
* Informed consent must be obtained, preferably prior, to photography with a mobile device. This applies for each and any such encounter and the purpose made clear (i.e. clinical, research, education, publication, etc.). Patients should also be made aware that they may request a copy of a picture or for a picture to be deleted.
* A patient's consent to use electronic transmission does not relieve a physician of their duty to protect the confidentiality of patient information. Also, a patient's consent cannot override other jurisdictionally mandated security requirements.
* All patient consents (including verbal) should be documented. The acquisition and recording of patient consent for medical photography/dissemination may be held to a high standard of accountability due to the patient privacy and confidentiality issues inherent in the use of this technology. Written and signed consent is encouraged.
* Consent should be considered as necessary for any and all photography involving a patient, whether or not that patient can be directly recognized, due to the possibility of linked information and the potential for breach of privacy. The definition of non-identifiable photos must be carefully considered. Current technologies such as face recognition and pattern matching (e.g. skin markers, physical structure, etc.), especially in combination with identifying information, have the potential to create a privacy breach.
* Unsecure text and email messaging requires explicit patient consent and should not be used unless the current gold standards of security are not accessible. For a patient-initiated unsecure transmission, consent should be clarified and not assumed.
* Transmission of photos and patient information should be encrypted as per current-day gold standards (presently, end-to-end encryption (E2EE)) and use only secure servers that are subject to Canadian laws. Explicit, informed consent is required otherwise due to privacy concerns or standards for servers in other jurisdictions. Generally, free internet-based communication services and public internet access are unsecure technologies and often operate on servers outside of Canadian jurisdiction.
* Efforts should be made to use the most secure transmission method possible. For data security purposes, identifying information should never be included in the image, any frame of a video, the file name, or linked messages.
* The sender should always ensure that each recipient is intended and appropriate and, if possible, receipt of transmission should be confirmed by the recipient.
* Storing images and data on a smart-device should be limited as much as possible for data protection purposes.
* Clinical photos, as well as messages or other patient-related information, should be completely segregated from the device's personal storage. This can be accomplished by using an app that creates a secure, password-protected folder on the device.
* All information stored (on internal memory or cloud) must be strongly encrypted and password protected. The security measures must be more substantial than the general password unlock feature on mobile devices.
* Efforts should be made to dissociate identifying information from images when images are exported from a secure server. Media should not be uploaded to platforms without an option for securely deleting information without consent from the patient, and only if there are no better options. Automatic back-up of photos to unsecure cloud servers should be deactivated. Further, other back-up or syncing options that could lead to unsecure server involvement should be ascertained and the risks mitigated.
4. Cloud storage should be on a Canadian and SOCII certified server. Explicit, informed consent is required otherwise due to privacy concerns for servers in other jurisdictions.
5. AUDIT & RETENTION
* It is important to create an audit trail for the purposes of transparency and medical best practice. Key information includes patient and health information, consent type and details, pertinent information regarding the photography (date, circumstance, photographer), and any other important facts such as access granted/deletion requests.
* Access to the stored information must be by the authorized physician or health care provider and for the intended purpose, as per the consent given. Records should be stored such that it is possible to print/transfer as necessary.
* Original photos should be retained and not overwritten.
* All photos and associated messages may be considered part of the patient's clinical records and should be maintained for at least 10 years or 10 years after the age of majority, whichever is longer. When possible, patient information (including photos and message histories between health professionals) should be retained and amalgamated with a patient's medical record. Provincial regulations regarding retention of clinical records may vary and other regulations may apply to other entities - e.g. 90 years from date of birth applies to records at the federal level.
* It may not be allowable to erase a picture if it is integral to a clinical decision or provincial, federal, or other applicable regulations require their retention.
* Any breach should be taken seriously and should be reviewed. All reasonable efforts must be made to prevent a breach before one occurs. A breach occurs when personal information, communication, or photos of patients are stolen, lost, or mistakenly disclosed. This includes loss or theft of one's mobile device, texting to the wrong number or emailing/messaging to the wrong person(s), or accidentally showing a clinical photo that exists in the phone's personal photo album.
* It should be noted that non-identifying information, when combined with other available information (e.g. a text message with identifiers or another image with identifiers), can lead to highly accurate re-identification.
* At present, apps downloaded to a smart-device for personal use may be capable of collecting and sharing information - the rapidly changing nature of this technology and the inherent privacy concerns requires regular attention. Use of specialized apps designed for health-information sharing that help safeguard patient information in this context is worth careful consideration.
* Having remote wipe (i.e. device reformatting) capabilities is an asset and can help contain a breach. However, inappropriate access may take place before reformatting occurs.
* If a smartphone is strongly encrypted and has no clinical photos stored locally then its loss may not be considered a breach.
* In the event of a breach any patient potentially involved must be notified as soon as possible. The CMPA, the organization/hospital, and the Provincial licensing College should also be contacted immediately. Provincial regulations regarding notification of breach may vary.
Approved by the CMA Board of Directors March 2018
i Heyns M†, Steve A‡, Dumestre DO‡, Fraulin FO‡, Yeung JK‡
† University of Calgary, Canada
‡ Section of Plastic Surgery, Department of Surgery, University of Calgary, Canada
1 Chan N, Charette J, Dumestre DO, Fraulin FO. Should 'smart phones' be used for patient photography? Plast Surg (Oakv). 2016;24(1):32-4.
2 Unpublished - Heyns M, Steve A, Dumestre DO, Fraulin FO, Yeung J. Canadian Guidelines on Smartphone Clinical Photography.
Health systems around the world are struggling with how to best meet the health needs of their populations. Health leaders speak with urgency about the need to improve the individual experience of care, improve the health of populations, and maximize return on investments. Physicians concur - they are continually focused on providing better care to their patients.
Concurrently, concerns over patient safety have arisen over the last two decades, rooted in studies of adverse events. The incidence of adverse events (AEs) in acute care hospitals has been reported in the United States (US),1,2,3 Australia,4 United Kingdom,5 and Canada.6 Between 5% and 20% of patients admitted to hospital experience one or more AEs; between 36.9% - 51% of these AEs are preventable; and AEs contribute billions of dollars through additional hospital stays as well as other costs to the system, patients and the broader society.7 Leape et al. maintain that more than two-thirds of AEs are preventable.8 These outcomes have prompted decision makers, policy makers and healthcare providers to examine contributing factors, including the increasingly complex health system and its impact on the well-being of providers.
Patient safety and physician well-being are the key drivers leading to restrictions on resident and/or physician duty hours aimed at reducing their fatigue. The European Working Time Directive (EWTD) was first established in 1993 to place limits on all workers' hours throughout Europe under the umbrella of health and safety legislation. That directive included physicians but excluded doctors in training. In 2000, a new directive passed to include the "junior doctor" constituency accompanied by a requirement that by 2009 all health systems in the European Union limit resident work to a maximum of 48 hours averaged per week. The intention was to improve the working lives of doctors in training and to increase patient safety. A systematic review on the impact of the EWTD on postgraduate medical training, patient safety, or clinical outcomes found studies to be of poor quality with conflicting results.9
In 2003, the Accreditation Council for Graduate Medical Education (ACGME) in the US adopted a set of duty hour regulations for physicians in training. The ACGME issued revised regulations that went into effect in July 2011, reflecting the recommendations of a 2008 Institute of Medicine report Resident Duty Hours: Enhancing Sleep, Supervision, and Safety, calling for elimination of extended duty shifts (more than 16 hours) for first year residents, increasing days off, improving sleep hygiene by reducing night duty and providing more scheduled sleep breaks, and increasing oversight by more senior physicians.10 The Institute of Medicine's report bases its recommendations on the growing body of research linking clinician fatigue and error.
In 2013, the National Steering Committee on Resident Duty Hours released Canada's first comprehensive, collaborative and evidence-based report on fatigue and duty hours for Canada's approximately 12,000 residents. The Committee stresses that a comprehensive approach is necessary in order to enhance safety and wellness outcomes. Fatigue risk management is a predominant theme in the recommendations.
Fatigue management systems are in place in other sectors/industries that have a low threshold for adverse outcomes including aviation, transportation, and the Department of National Defence. In 2010, the Canadian Nurses Association released a position statement Taking Action on Nurse Fatigue that speaks to system, organizational and individual level responsibilities of registered nurses.
There are currently no specific policies in Canada for physicians in practice with respect to fatigue management. Given the heterogeneity of medical practice (i.e. various specialties) and of the practice settings (i.e. rural and remote versus urban, clinic versus hospital, etc.), the solutions emanating from a fatigue management policy may be different - one size will not fit all.
Impact of Physician Fatigue
Sleep deprivation is the condition of not having enough sleep and can be either chronic or acute. It impairs cognitive and behavioural performance. "Sleep is required for the consolidation of learning and for the optimal performance of cognitive tasks. Studies of sleep deprivation have shown that one night without sleep negatively affects the performance of specific higher cognitive functions of the prefrontal cortex and can cause impairment in attention, memory, judgment, and problem solving."(p. 1841)11 A seminal study by Williamson and Feyer found that after 17-19 hours without sleep, performance on some cognitive and motor performance tests was equivalent or worse than that at a blood alcohol concentration (BAC) of 0.05%.12 Wakefulness for 24 hours is equivalent to a blood alcohol level of 0.10%.13
A chronic sleep-restricted state can cause fatigue, which is a subjective feeling of tiredness, lack of energy and motivation. A large body of research exists linking sleep deprivation/fatigue, performance and adverse patient outcomes, particularly for medical residents. 14,15,16,17,18,19, 20, 21,22, 23,24 However, literature on the impact on performance varies based on a number of factors. There are significant inter-individual differences in the global response to sleep loss, as well as significant intra-individual variations in the degree to which different domains of neurobehavioral function (e.g., vigilance, subjective sleepiness, and cognitive performance) are affected. Inter-individual differences are not merely a consequence of variations in sleep history. Rather, they involve trait-like differential vulnerability to impairment from sleep loss. 25
Evidence suggests an inconclusive relationship between duty hour reductions (primarily those implemented in the US) and patient safety, suggesting that restrictions on consecutive duty hours have not had the anticipated impact on this crucial outcome as anticipated.26 Several large studies have revealed only neutral or slightly improved patient mortality and other clinical parameters since implementation of the ACGME work hour limits in the US.27,28, 29,30 In complex and ever changing health systems, it is difficult to isolate the impact of restricted duty hours alone.
Research on the effects of practicing physician sleep deprivation and extended work shifts on clinical outcomes is limited and inconclusive.31, 32
The issue of physician fatigue is complex, and is affected by much more than duty hours. Other contributing factors affect performance including work patterns, individual response to sleep loss, experience of the worker, the context of which sleep deprivation is necessary, hours of actual sleep, patient volume, patient turnover and patient acuity, environmental factors, personal stressors, workload, etc. Limiting work hours alone is not sufficient to address sleep deprivation among physicians. Reduced or disturbed periods of sleep, more consecutive days or nights of work, shift variability, and the volume of work all increase fatigue and thus can contribute to errors.
One of the biggest concerns with a fatigue management strategy is continuity of care, linked to the number of transfers of care (handover) among providers. Transfers of care inevitably increase in an environment of work hour limitations.33, 34 Handovers are considered critical moments in the continuity of patient care and have been identified as a significant source of hospital errors, often related to poor communication. There is a growing body of literature on how to do these well and how to teach this well. This is an important skill for physicians in the context of a fatigue management strategy: "Standardization of the handover process has been linked to a reduction in the number of errors related to information transfers. In addition, effective mechanisms for the transfer of information at transition points have been recognized as patient safety enablers."35
Provider well-being (physical, mental, occupational) is linked to system performance and patient outcomes. It is affected by fatigue and work patterns including night shift and extended hours. Comprehensive, systematic reviews of the health effects of on-call work in 2004 showed that nighttime work interrupted sleep patterns, aggravated underlying medical conditions, and increased the risk of cardiovascular, gastrointestinal, and reproductive dysfunction.36,37.38 Other research suggests an elevated risk of breast cancer,39,40 prostate cancer,41 colorectal cancer,42 asthma43, diabetes,44 and epilepsy45 for shift workers. Disruption of the body's circadian rhythms is thought to be one of the main pathways for adverse health effects from shift work, particularly for work schedules that involve night work.
Given that 24-hour work is unavoidable in various industries, including healthcare, researchers have evaluated different shift schedules designed to reduce some of the negative health effects of working at night. Optimal shift schedules are aligned as much as possible with the circadian rhythm, promote adaptation of the circadian rhythm with shift work, reflect workers' needs and preferences, and meet organizational or productivity requirements. The following interventions appear to have the most beneficial effects on the health of shift workers:46
* Schedule changes including changing from backward (counterclockwise) to forward (clockwise) rotation, from eight hour to 12 hour shifts, and flexible working conditions, self-scheduling, and ergonomic shift scheduling principles
* Controlled exposure to light and day;
* Behavioural approaches such as physical activity, scheduled naps and education about sleep strategies; and
* Use of pharmacotherapy (i.e. caffeine and melatonin) to promote sleep, wakefulness, or adaptation
Sleep deprivation and on-call shifts consistently point to deterioration of mood resulting in depression, anger, anxiety, hostility, and decreased vigilance.47 ,48, 49 A Canadian study found that shift workers reported significantly higher burnout, emotional exhaustion, job stress and psychosomatic health problems (e.g. headaches, upset stomach, difficulty falling asleep) than workers on a regular day schedule.50 Prolonged duty hours by residents has been found to contribute to marital problems, pregnancy complications, depression, suicide and substance abuse,51 as well as serious conflicts with attending physicians, other residents, and nurses, in addition to increased alcohol use and instances of unethical behaviour.52 Surprisingly however, the abolishment of 24-hour continuous medical call duty for general surgery residents at one facility in Quebec was associated with self-reported poorer quality of life.53
In contrast to other recommendations on the health benefits of 8 hr shifts, the risk of a work safety incident increases markedly after more than eight hours on duty. The risk in the twelfth hour is almost double than in the eighth hour (and more than double the average risk over the first eight hours on duty).54 Extended work duration and nighttime work by interns is associated with an increased risk of reported percutaneous injuries (PIs).55 Fatigue was reported more often as a contributing factor for nighttime compared with daytime injuries. Fatigue was also more commonly reported as a contributing factor to PIs that occurred after extended work than those that occurred after non-extended work.56 Other research found that residents were most exposed to blood-borne pathogens through needle punctures or cuts during overnight duty periods.57
Health care facilities that have physicians working in them have a role in supporting and promoting provider well-being, including providing enablers of extending and continuing resiliency such as nutritious food, on call rooms, appropriate numbers of staff, locums, etc. They also have a role in working jointly and collaboratively with physicians to ensure that on-call schedules do not place work demands on individual physicians that prevent the physicians from providing safe patient care and service coverage. For example, research with emergency physicians suggests that a nap at 3 AM improves performance in physicians and nurses at 7:30 AM compared to a no-nap condition despite the fact that memory temporarily worsened immediately after the nap.58
Individual resilience, intergenerational differences, illness-related issues, as well as family commitments also need to be considered. Physicians should also be encouraged to take the necessary time to rest and recover on their time off. The obligation of physicians to provide after hour coverage and care is unavoidable and should be considered by an individual when they choose a career in medicine, and as a physician in managing their schedule/call.
A review of 100 studies from around the world indicates the culture of medicine contributes to doctors ignoring the warning signs of fatigue and stress and in many cases suffering from undiagnosed ailments such as stress and depression, or from burnout.59 The authors suggest the culture of medicine is such that doctors feel they don't need help; they put their patients first. Of the 18% of Canadian doctors who were identified as depressed, only a quarter of them considered getting help and only two per cent actually did. The report suggests that burnout from working long hours and sleep deprivation because of understaffing seems to be the biggest problem worldwide.60 The Canadian Medical Protective Association (CMPA) states that physicians should consider their level of fatigue and if they are clinically fit to provide treatment or care.61 Fatigue is not a sign of weakness. All members of the health care team should support their colleagues in recognizing and managing sleep deprivation and fatigue.
Physician fatigue has several ethical dimensions. The Canadian Medical Association Code of Ethics states that physicians have an ethical responsibility to self-manage their fatigue and well-being. 62 However, physicians must be trained and competent to know their own limits and evaluate their own fatigue level and well-being. The system must then support physicians in this recognition. The doctrine of informed consent is another dimension of physician fatigue. If physician fatigue is an added risk for any aspect of patient care, whether it is surgical or medical, elective or emergent, then some have argued that the doctrine of informed consent suggests that physicians have an obligation to inform patients of that risk.63 ,64 "The medico-legal considerations for physicians centre on the ethical duty to act in the best interests of their patients. This may mean that if a physician feels that his or her on-call schedule endangers or negatively impacts patient care, reasonable steps are taken to ensure patients do not suffer as a result and that the physician is able to continue providing an adequate level of care for patients."65
Addressing physician fatigue may have workforce implications.
Physician workload is multifaceted comprised of clinical, research, education and administrative activities. If physician workload or duty hours are reduced, any one of these activities may be impacted.
It has been suggested that implementing fatigue management strategies such as a workload ceiling for physicians may result in a greater need for physicians and thus increase system costs. However, new models of team based care delivery that incorporate technology, reduce redundancy, utilize a team based approach, and optimize the role of physicians offer an opportunity to better manage physician fatigue without necessarily requiring more physicians. Other strategies also need to be explored to improve the on-the-ground efficiency of physicians.
Some of the strategies to address practicing physician sleep deprivation/fatigue such as scheduling changes and reduced workload may affect access to care, including wait times. Surgeons or others may have to cancel surgeries or other procedures because of fatigue and hours of work, forcing rescheduling of surgery/procedures and potentially increasing wait times. This is particularly relevant given Canada's large geography and varied distribution of physicians. Therefore, flexibility in strategies to address physician sleep deprivation/fatigue are needed to reflect the variety of practice types and settings in existence across the country, in particular solo practices; rural, remote and isolated sites; community locations; etc. The same holds true for smaller specialties, which has been the experience in the UK with the implementation of the EWTD.
Fatigue management is a competency that needs to be taught, modelled, mentored, and evaluated across the medical education continuum, from medical student to practicing physician.
1. Educate physicians about the effects of sleep deprivation and fatigue on the practice of medicine and physician health, and how to recognize and manage their effects.
2. Create a national tool-box of self-awareness tools and fatigue management strategies and techniques.
3. Advocate for the integration of fatigue management into the continuum of medical education.
4. Advocate for the creation of system enablers with the flexibility to:
* Consider the full workload of physicians (clinical, teaching, administrative, research, etc.);
* Optimize scheduling to coordinate on call and other patient care following call; and
* Implement organizational/institutional level fatigue risk management plans.
5. Develop and advocate for implementation of standardized handover tools.
6. Enhance and reaffirm a culture within medicine that focuses on patient-centered care.
7. Reaffirm the culture shift within medicine that encompasses physician well-being.
8. Encourage physicians treating physicians to be aware of the aggravating effects of fatigue on their well-being and practice.
Physicians are interested in how to best meet the needs of the population, in continually improving the care provided to Canadians. To do so requires that they also care for themselves including managing the effects of sleep deprivation and fatigue. It is a complex issue that requires multifaceted solutions. Strategies must address physician fatigue at an individual, organizational/institutional and system level.
1 Leape, LL, Brennan, TA, Laaird, N, Lawthers, AG, Logalio, AR, Barnes, BA et al. (1991).The nature of adverse events in hospitalized patients. New England Journal of Medicine 324 (6): 377-384
2 Brennan, TA, Leape, LL, Nan, M, et al. (1991). Incidence of adverse events and negligence in hospitalized patients: Results of the Harvard Medical Practice Study I. New England Journal of Medicine 324:370-376.
3 Thomas, E., Studdert, D., Burstin, H., et al. (2000). Incidence and types of adverse events and negligent care in Utah and Colorado. Medical Care 38(3): 261-71.
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6 Baker, G., Norton, P., Flintoft, V., Balis, R., Brown, A., Cox, J., et al. (2004). The Canadian adverse event study: the incidence of adverse events among hospitalized patients in Canada. Canadian Medical Association Journal, 170(11): 1678-1686.
7 Jeffs, L., Law, M., Baker, G., & Norton, P. (2005). Patient Safety Research in Australia, United Kingdom, United States and Canada: A Summary of Research Priority Areas, Agenda-Setting Processes And Directions for Future Research in the Context of their Patient Safety Initiatives. Retrieved from http://www.patientsafetyinstitute.ca/English/news/eventProceedings/Documents/2005%20Research%20Retreat%20-%20Patient%20Safety%20Research%20Backgrounder%20Paper.pdf
8 Leape, L., Brennan, T., Laaird, N., Lawthers, A., Logalio, A., Barnes, B. et al. (1991). The nature of adverse events in hospitalized patients. New England Journal of Medicine 324 (6): 377-384.
9 Moonesinghe, S., Lowery, J., Shahi, N., Millen, A., & Beard, L. (2011). Impact of reduction in working hours for doctors in training on postgraduate medical education and patients' outcomes: systematic review. BMJ 342:d1580.
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21 Lockley, S., Cronin, J., Evans, E., Cade, B., Lee, C., et al. (2004). Effect of Reducing Interns' Weekly Work Hours on Sleep and Attentional Failures. N Engl J Med 351: 1829-1837.
22 Landrigan, C., Rothschild, J., Cronin, J., Kaushal, R., Burdick, E., et al. (2004). Effect of Rreducing Interns' Work Hours on Serious Medical Errors in Intensive-care Units. N Engl J Med 351: 1838-1848.
23 Barger, L., Ayas, N., Cade, B., Cronin, J., Rosner, B., et al. (2006). Impact of Extended-Duration Shifts on Medical Errors, Adverse Events, and Attentional Failures. PLoS Med 3(12): 2440-2448.
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25 Van Dongen, H., Baynard, M., Maislin, G., et al. (2004). Systematic interindividual differences in neurobehavioral impairment from sleep loss: evidence of a trait-like differential vulnerability. Sleep 27: 423-433.
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28 Volpp, K., Rosen, A., Rosenbaum, P., et al. (2007). Mortality Among Patients in VA Hospitals in the First 2 Years Following ACGME Resident Duty Hour Reform. JAMA 298(9): 984-992.
29 Antiel, R., Reed, D., Van Arendonk, K., Wightman, S., Hall, D., Porterfield, J., et al. (2013). Effects of Duty Hour Restrictions on Core Competencies, Education, Quality of Life, and Burnout Among General Surgery Interns. JAMA Surg 148(5):448-455.
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32 Sharpe, J., Weinberg, J., Magnotti, L., Nouer, S., Yoo, W., Zarzaur, B. et al. (2013). Outcomes of Operations Performed by Attending Surgeons after Overnight Trauma Shifts. J Am Coll Surg 216:791- 799.
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35 Canadian Medical Protective Association. (2013). CMPA Risk Fact Sheet: Patient Handover. Retrieved January 13, 2014 from https://oplfrpd5.cmpa-acpm.ca/documents/10179/300031190/patient_handovers-e.pdf
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39 Shields, M. (2002). Shift work and health. Health Reports 13(4):11-33.
40 Fritschi, L., Glass, D., Heyworth, J., Aronson, K., Girschik, J., Boyle, T., et al. (2011). Hypotheses for mechanisms linking shiftwork and cancer. Medical Hypotheses 77:430-436.
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Vision for e-Prescribing: a joint statement by the Canadian Medical Association and the Canadian Pharmacists Association
By 2015, e-prescribing will be the means by which prescriptions are generated for Canadians.
e-Prescribing is the secure electronic creation and transmission of a prescription between an authorized prescriber and a patient's pharmacy of choice, using clinical Electronic Medical Record (EMR) and pharmacy management software.
Health Information Technology (HIT) is an enabler to support clinicians in the delivery of health care services to patients. The Canadian Medical Association (CMA) and the Canadian Pharmacists Association (CPhA) each have identified e-prescribing as a key tool to deliver better value to patients. The integration of HIT into clinics and health care facilities where physicians and pharmacists provide care is a priority for both associations1.
As part of its Health Care Transformation initiative, the CMA highlighted the need to accelerate the introduction of e-prescribing in Canada to make it the main method of prescribing. In its policy on optimal prescribing the CMA noted that one of the key elements was the introduction of electronic prescribing. The CPhA, as part of its Blueprint for Pharmacy Implementation Plan, highlights information and communication technology, which includes e-prescribing, as one of five priority areas.
We applaud the ongoing efforts of Canada Health Infoway, provinces and territories to establish Drug Information Systems (DIS) and the supporting infrastructure to enable e-prescribing. We urge governments to maintain e-prescribing as a priority and take additional measures to accelerate their investments in this area.
It is our joint position that e-prescribing will improve patient care and safety. e-Prescribing, when integrated with DIS, supports enhanced clinical decision-making, prescribing and medication management, and integrates additional information available at the point of care into the clinical workflow.
The following principles should guide our collective efforts to build e-prescribing capability in all jurisdictions:
* Patient confidentiality and security must be maintained
* Patient choice must be protected
* Clinicians must have access to best practice information and drug cost and formulary data
* Work processes must be streamlined and e-prescribing systems must be able to integrate with clinical and practice management software and DIS
* Guidelines must be in place for data sharing among health professionals and for any other use or disclosure of data
* The authenticity and accuracy of the prescription must be verifiable
* The process must prevent prescription forgeries and diversion
* Pan-Canadian standards must be set for electronic signatures
Benefits of e-Prescribing
A number of these benefits will be realized when e-prescribing is integrated with jurisdictional Drug Information Systems (DIS).
o Improves patient safety and overall quality of care
o Increases convenience for dispensing of new and refill prescriptions
o Supports collaborative, team-based care
o Supports a safer and more efficient method of prescribing and authorizing refills by replacing outdated phone, fax and paper-based prescriptions
o Eliminates re-transcription and decreases risk of errors and liability, as a prescription is written only once at the point-of-care
o Supports electronic communications between providers and reduces phone calls and call-backs to/from pharmacies for clarification
o Provides Warning and Alert systems at the point of prescribing, supporting clinician response to potential contraindications, drug interactions and allergies
o Facilitates informed decision-making by making medication history, drug, therapeutic, formulary and cost information available at the point of prescribing
* Health Care System:
o Improves efficiency and safety of prescribing, dispensing and monitoring of medication therapy
o Supports access to a common, comprehensive medication profile, enhancing clinical decision-making and patient adherence
o Increases cost-effective medication use, through improved evidence-based prescribing, formulary adherence, awareness of drug costs and medication management
o Improves reporting and drug use evaluation
While evidence of the value of e-prescribing is established in the literature, its existence has not fostered broad implementation and adoption. In Canada, there are a number of common and inter-related challenges to e-prescribing's implementation and adoption. These include:
* Improving access to relevant and complete information to support decision-making
* Increasing the level of the adoption of technology at the point of care
* Focusing on systems-based planning to ensure continuum-wide value
* Integrating e-prescribing into work processes to gain support from physicians, pharmacists and other prescribers
* Increasing leadership commitment to communicate the need for change, remove barriers and ensure progress
* Updating legislation and regulation to support e-prescribing
Enabling e-Prescribing in Canada
CMA and CPhA believe that we can achieve the vision that is set out in this document and address the aforementioned challenges by working collectively on five fronts:
* Health care leadership in all jurisdictions and clinical organizations must commit to make e-prescribing a reality by 2015
* Provinces and territories, with Canada Health Infoway, must complete the building blocks to support e-prescribing by increasing Electronic Medical Record (EMR) adoption at the point of care, finishing the work on the Drug Information Systems (DIS) in all jurisdictions and building the connectivity among the points of care and the DIS systems
* Pharmacist and medical organizations in conjunction with provinces, territories and Canada Health Infoway must identify clear benefits for clinicians (enhancing the effectiveness of care delivery and in efficiencies in changing workflows) to adopt e-prescribing and focus their efforts on achieving these benefits in the next three years
* Provinces, territories and regulatory organizations must create a policy/regulatory environment that supports e-prescribing which facilitates the role of clinicians in providing health care to their patients
* Provinces and territories must harmonize the business rules and e-health standards to simplify implementation and conformance by software vendors and allow more investment in innovation.
1 Health Care Transformation in Canada, Canadian Medical Association, June 2010; Blueprint for Pharmacy Implementation Plan, Canadian Pharmacists Association, September 2009