In EPAs we trust, is quality and safety a must? A cross-specialty analysis of entrustable professional activity guides.

PURPOSE: The inclusion of quality improvement (QI) and patient safety (PS) into CanMEDS reflects an expectation that graduating physicians are competent in these areas upon training completion. To ensure that Canadian postgraduate specialty training achieves this, the translation of QI/PS competencies into training standards as part of the implementation of competency-based medical education requires special attention. METHODS: We conducted a cross-specialty, multi-method analysis to examine how QI/PS was incorporated into the EPA Guides across 11 postgraduate specialties in Canada. RESULTS: We identify cross-specialty variability in how QI/PS is incorporated, positioned, and emphasized in EPAs and milestones. QI/PS was primarily referenced alongside clinical activities rather than as a sole competency or discrete activity. Patterns were characterized in how QI/PS became incorporated into milestones through repetition and customization. QI/PS was also decoupled, conceptualized, and emphasized differently across specialties. CONCLUSIONS: Variability in the inclusion of QI/PS in EPAs and milestones has important implications considering the visibility and influence of EPA Guides in practice. As specialties revisit and revise EPA Guides, there is a need to balance the standardization of foundational QI/PS concepts to foster shared understanding while simultaneously ensuring context-sensitive applications across specialties. Beyond QI/PS, this study illuminates the challenges and opportunities that lie in bridging theoretical frameworks with practical implementation in medical education, prompting broader consideration of how intrinsic roles and emergent areas are effectively incorporated into competency-based medical education.

A Cost-Effective Inertial Measurement System for Tracking Movement and Triggering Kinesthetic Feedback in Lower-Limb Prosthesis Users.

Advances in lower-limb prosthetic technologies have facilitated the restoration of ambulation; however, users of such technologies still experience reduced balance control, also due to the absence of proprioceptive feedback. Recent efforts have demonstrated the ability to restore kinesthetic feedback in upper-limb prosthesis applications; however, technical solutions to trigger the required muscle vibration and provide automated feedback have not been explored for lower-limb prostheses. The study's first objective was therefore to develop a feedback system capable of tracking lower-limb movement and automatically triggering a muscle vibrator to induce the kinesthetic illusion. The second objective was to investigate the developed system's ability to provide kinesthetic feedback in a case participant. A low-cost, wireless feedback system, incorporating two inertial measurement units to trigger a muscle vibrator, was developed and tested in an individual with limb loss above the knee. Our system had a maximum communication delay of 50 ms and showed good tracking of Gaussian and sinusoidal movement profiles for velocities below 180 degrees per second (error < 8 degrees), mimicking stepping and walking, respectively. We demonstrated in the case participant that the developed feedback system can successfully elicit the kinesthetic illusion. Our work contributes to the integration of sensory feedback in lower-limb prostheses, to increase their use and functionality.

Skin Stretch Enhances Illusory Movement in Persons with Lower-Limb Amputation.

Performance of lower limb prostheses is related not only to the mechanical design and the control scheme, but also to the feedback provided to the user. Proprioceptive feedback, which is the sense of position and movement of one's body parts, can improve the utility as well as facilitate the embodiment of the prosthetic device. Recent studies have shown that proprioceptive kinesthetic (movement) sense can be elicited when non-invasively vibrating a muscle tendon proximal to the targeted joint. However, consistency and quality of the elicited sensation depend on several parameters and muscle tendons after lower limb amputation may not always be accessible. In this study, we developed an experimental protocol to quantitatively and qualitatively assess the elicited proprioceptive kinesthetic illusion when non-invasively vibrating a muscle belly. Furthermore, we explored ways to improve consistency and strength of the illusion by integrating another non-invasive feedback method, namely cutaneous information manipulation via skin stretch. Our preliminary results from tests conducted with a person with transtibial (below knee) amputation show that stretching skin while vibrating a muscle belly on the residual limb provided a stronger and more consistent kinesthetic illusion (90%) than only vibrating the muscle (50%). In addition, we found that stretching skin enhances the range (1.5 times) and speed (3.5 times) of the illusory movement triggered by muscle vibration. These findings may enable the development of mechanisms for controlling feedback parameters in closing the control loop for various walking routines, which may improve performance of lower limb prostheses.