Virtual Reality as a Tool for Eliciting Empathetic Behaviour in Carers: An Integrative Review

The Dual Importance of Virtual Reality Usability in Rehabilitation: A Focus on Therapists and Patients

Virtual reality (VR) has advanced in medical education and rehabilitation from basic graphical applications due to its ability to generate a virtual three-dimensional (3D) environment. This environment is mostly used to practice professional skills, plan surgery procedures, simulate surgeries, display 3D anatomy, and rehabilitate various disorders. VR has transformed the field of rehabilitation therapy by providing immersive and engaging experiences that go beyond traditional bounds, significantly improving patient care and therapeutic results. Considering the direct impact of VR on the efficacy of the treatment for both therapists and patients, its dual significance for usability and user experience cannot be overstated. The purpose of this article is to determine the synergistic association between VR accessibility and the rehabilitation process, highlighting the significance of VR technology in designing the future of rehabilitation therapy and demonstrating how advancing VR technology can improve therapeutic outcomes despite overcoming obstacles encountered during VR usage. In conclusion, VR offers a personalized, efficient, interesting, and engaging rehabilitative environment for patients, while also assisting therapists in cultivating empathy and efficiency and encouraging innovative approaches in treatment procedures.

The Present and Future of Virtual Reality in Medical Education: A Narrative Review

Virtual reality (VR) uses computer-generated and three-dimensional environments to create immersive experiences through the use of interactive devices that simulate virtual environments in many forms, such as 3D, screen-based, or room-based. Users can engage in the environment with objects, characters, and scenes, making individuals assume they are experiencing a real-life scenario. VR has been adopted across medical and nursing fields to supplement clinically relevant and practical teaching. However, the effectiveness of this interactive form of learning has come a long way with improvements in accessibility, cost, and technicalities. The immersive simulated environment that VR has to offer today initially began with screen-based learning and then the 360-video method. These previously sought-out methods were eventually found to disconnect the students from engaging in the learning environment that present-day VR systems are designed to provide. Interactive VR offers a dynamic platform for medical training. These simulations benefit the learner by allowing them to interact within case scenarios and virtual wards, as well as with patients, colleagues, and relatives. To mimic real-life encounters, the student can take a patient's history and physical exam, investigate, diagnose, and provide treatment. The simulated patient can express emotions, concerns, and signs of a poor state of health. All these factors play into a healthcare provider's competency to think critically and clinically in decision-making. This practice is now being used in many surgical programs and medical education curricula. The use of simulation in VR is continuously being proven to decrease injury, increase operation speed, and improve overall outcomes in patient-centered care. VR simulation differs from in-person simulation training in that the VR modality of learning is more accessible and replicable than the latter. By comparing research studies and reviews of medical programs that incorporated VR into their curricula, we were able to assess the state of VR in medical education and where this technology could lead to future implementation in medical programs. Our review aimed to give insight into the existing evidence, the gaps in the use of VR in medical education, and the potential benefits this modality of learning can have going forward in this field of study. Medical students have demonstrated significantly enhanced knowledge gain when using immersive interactive VR over screen-based learning. Given the improvements in students' performance due to these dynamic and collaborative learning experiences, immersive VR training will become a standard in the development of clinical skills and ensure patient safety. Although the emphasis on empathy began later in the journey of gaining VR as a part of medical education, there is a need to gain those skills as early as possible in medical school. Implementing the use of VR as a supplement in medical education allows students to practice simulated patient encounters along with an array of different academic endeavors. By doing so, students will gain competency and confidence as they encounter patients during their clinical rotations and clinical practice.

Dementia Simulation for Family Caregivers of Persons With Dementia: A Scoping Review

BACKGROUND

Alzheimer's disease and related dementias are becoming increasingly prevalent worldwide. Persons with dementia receive substantial assistance from family caregivers over extended periods of time. Family caregivers of persons with dementia are twice as likely to report physical, emotional, and financial challenges related to caregiving compared with other types of family caregivers. Empathy has been demonstrated to improve caregivers' quality of life and their relationships with care recipients.

OBJECTIVE

This scoping review examines the current literature on the effects of dementia simulation on empathy levels in family caregivers of persons with dementia.

METHODS

A librarian-assisted search of 4 databases-PubMed, CINAHL (Cumulative Index to Nursing and Allied Health Literature), PsycINFO, and Scopus-was conducted. Key terms included "dementia," "family caregivers," and "simulation." To broaden reference retrieval, "empathy" was not used as a key term but remained an inclusion criterion during reference screening. Data extraction of relevant references was completed.

RESULTS

The search yielded 212 citations. Seven eligible dementia simulation studies were identified, including 1 randomized controlled trial, 3 quasi-experimental studies, and 3 qualitative research studies. Only 3 of the 7 studies focused specifically on family caregivers of persons with dementia.

CONCLUSIONS

Qualitative data supported increased empathy in family caregivers, but quantitative findings on changes in empathy levels were inconclusive. Further research using quantitative or mixed-methods designs is necessary to support benefits of simulation on empathy for family caregivers of persons with dementia.

Increased medical student understanding of dementia through virtual embodiment

Given the growing prevalence of Alzheimer's disease (AD), we assessed the impact of virtually embodying someone with progressive AD. This pilot explored students' understanding of individuals' needs with dementia, as well as, the efficacy of virtual reality (VR) as a curricular tool. Second-year medical students (n = 150) completed a pre-survey, Embodied Labs, Inc. Beatriz Lab VR module, and a post-survey. Most students knew someone with dementia (72%), were a family member of someone with dementia (52%) or had worked with a patient (61%) with dementia. Using paired survey questions, students reported significant increases in understanding how their lives would be affected by dementia (71% vs. 94%) and the needs of a person with dementia (64% vs. 95%) after VR. They reported increased understanding of being a caregiver of someone with dementia (24% vs. 81%) and the impact it can have on the entire family (64% vs. 97%). Overall students agreed this simulation made them think about their approach to clinical skills (94%) and should be utilized more in the curriculum (76%). This pilot study indicated that this VR experience can be used to advance understanding of a person's experiences with dementia and that integrating VR into the medical curricula should be considered.

Artificial intelligence technologies and compassion in healthcare: A systematic scoping review

Background

Advances in artificial intelligence (AI) technologies, together with the availability of big data in society, creates uncertainties about how these developments will affect healthcare systems worldwide. Compassion is essential for high-quality healthcare and research shows how prosocial caring behaviors benefit human health and societies. However, the possible association between AI technologies and compassion is under conceptualized and underexplored.

Objectives

The aim of this scoping review is to provide a comprehensive depth and a balanced perspective of the emerging topic of AI technologies and compassion, to inform future research and practice. The review questions were: How is compassion discussed in relation to AI technologies in healthcare? How are AI technologies being used to enhance compassion in healthcare? What are the gaps in current knowledge and unexplored potential? What are the key areas where AI technologies could support compassion in healthcare?

Materials and methods

A systematic scoping review following five steps of Joanna Briggs Institute methodology. Presentation of the scoping review conforms with PRISMA-ScR (Preferred Reporting Items for Systematic reviews and Meta-Analyses extension for Scoping Reviews). Eligibility criteria were defined according to 3 concept constructs (AI technologies, compassion, healthcare) developed from the literature and informed by medical subject headings (MeSH) and key words for the electronic searches. Sources of evidence were Web of Science and PubMed databases, articles published in English language 2011-2022. Articles were screened by title/abstract using inclusion/exclusion criteria. Data extracted (author, date of publication, type of article, aim/context of healthcare, key relevant findings, country) was charted using data tables. Thematic analysis used an inductive-deductive approach to generate code categories from the review questions and the data. A multidisciplinary team assessed themes for resonance and relevance to research and practice.

Results

Searches identified 3,124 articles. A total of 197 were included after screening. The number of articles has increased over 10 years (2011, n = 1 to 2021, n = 47 and from Jan-Aug 2022 n = 35 articles). Overarching themes related to the review questions were: (1) Developments and debates (7 themes) Concerns about AI ethics, healthcare jobs, and loss of empathy; Human-centered design of AI technologies for healthcare; Optimistic speculation AI technologies will address care gaps; Interrogation of what it means to be human and to care; Recognition of future potential for patient monitoring, virtual proximity, and access to healthcare; Calls for curricula development and healthcare professional education; Implementation of AI applications to enhance health and wellbeing of the healthcare workforce. (2) How AI technologies enhance compassion (10 themes) Empathetic awareness; Empathetic response and relational behavior; Communication skills; Health coaching; Therapeutic interventions; Moral development learning; Clinical knowledge and clinical assessment; Healthcare quality assessment; Therapeutic bond and therapeutic alliance; Providing health information and advice. (3) Gaps in knowledge (4 themes) Educational effectiveness of AI-assisted learning; Patient diversity and AI technologies; Implementation of AI technologies in education and practice settings; Safety and clinical effectiveness of AI technologies. (4) Key areas for development (3 themes) Enriching education, learning and clinical practice; Extending healing spaces; Enhancing healing relationships.

Conclusion

There is an association between AI technologies and compassion in healthcare and interest in this association has grown internationally over the last decade. In a range of healthcare contexts, AI technologies are being used to enhance empathetic awareness; empathetic response and relational behavior; communication skills; health coaching; therapeutic interventions; moral development learning; clinical knowledge and clinical assessment; healthcare quality assessment; therapeutic bond and therapeutic alliance; and to provide health information and advice. The findings inform a reconceptualization of compassion as a human-AI system of intelligent caring comprising six elements: (1) Awareness of suffering (e.g., pain, distress, risk, disadvantage); (2) Understanding the suffering (significance, context, rights, responsibilities etc.); (3) Connecting with the suffering (e.g., verbal, physical, signs and symbols); (4) Making a judgment about the suffering (the need to act); (5) Responding with an intention to alleviate the suffering; (6) Attention to the effect and outcomes of the response. These elements can operate at an individual (human or machine) and collective systems level (healthcare organizations or systems) as a cyclical system to alleviate different types of suffering. New and novel approaches to human-AI intelligent caring could enrich education, learning, and clinical practice; extend healing spaces; and enhance healing relationships.

Implications

In a complex adaptive system such as healthcare, human-AI intelligent caring will need to be implemented, not as an ideology, but through strategic choices, incentives, regulation, professional education, and training, as well as through joined up thinking about human-AI intelligent caring. Research funders can encourage research and development into the topic of AI technologies and compassion as a system of human-AI intelligent caring. Educators, technologists, and health professionals can inform themselves about the system of human-AI intelligent caring.

VR for Pain Relief

The present chapter explores how immersive virtual reality (VR) systems can be used for pain research and treatment. Pain is a universal, yet entirely subjective and multifaceted unpleasant experience. One of the earliest VR studies on pain highlighted the role of attention in pain modulation. However, the role of body representation in pain modulation has also been described as a crucial factor. Through virtual reality systems, it is possible to modulate both attention to pain and body representation. In this chapter, first we define how immersive VR can be used to create the illusion of being present in immersive VR environments and argue why VR can be an effective tool for distracting patients from acute pain. However, distraction seems to be less useful in chronic pain treatment. Chronic pain can be highly disabling and can significantly impact not only the sufferer's quality of life, but also their perceptions of the bodily self. Close neural connections between the body matrix and pain open a chance for influencing pain through bodily illusions. This chapter explores approaches to inducing body ownership illusions in VR and discusses how they have been applied in pain research. The present chapter also covers a set of practical indications and methodological caveats of immersive VR and solutions for overcoming them. Finally, we outline several promising future research directions and highlight several yet unexplored areas.

Technologies to improve the participation of stroke patients in their home environment

PURPOSE

To identify possible technological solutions that can contribute to stroke patients' participation at home.

METHODS

In this qualitative case study, data on factors that negatively influenced participation at home were collected via semi-structured interviews with stroke patients (n = 6). Additionally, data on possible technologies to improve this participation were collected via a group interview with experts (n = 4). The domains "cognition, mobility, self-care, and getting along" (International Classification of Functioning, Disability and Health) guided the data collection and interpretation; open, axial and selective coding was part of the analysis.

RESULTS

Patients reported 21 factors negatively influencing participation at home, including psychological, cognitive, and physical factors. Experts suggested technological solutions regarding these factors to increase participation of stroke patients; digital assistants, apps, and virtual reality were frequently mentioned. To facilitate the use of these technologies, experts indicated the importance of involving patients in their design. They also suggested that rehabilitation specialists and family members could support the uptake and use of technologies.

CONCLUSIONS

Various technologies were identified by experts as having the potential to improve the participation of stroke patients in their homes. Future research may study the influence of these technologies on the actual participation of stroke patients at home.Implications for rehabilitationThe identified technological solutions can support rehabilitation specialists in guiding stroke patients towards technologies that can support a patient's participation at home.Rehabilitation specialists can be champions in introducing, recommending and promoting technologies to stroke patients and their families, as well as in training them to use technologies.Virtual reality as a technology can be part of rehabilitation, not only to train stroke patients in daily life activities but also to increase empathy and understanding in caregivers and carers on stroke impairments.Rehabilitation specialists can recommend technologies integrated in daily life and presented as general consumer goods; stroke patients are more likely to adopt these kind of technologies.

Expanding Aesthetics

This paper seeks to expand traditional aesthetic dimensions of design beyond the limits of human capability in order to encompass other species' sensory modalities. To accomplish this, the idea of inclusivity is extended beyond human cultural and personal identities and needs, to embrace multi-species experiences of places, events and interactions in the world. This involves drawing together academic perspectives from ecology, neuroscience, anthropology, philosophy and interaction design, as well as exploring artistic perspectives and demonstrating how these different frames of reference can inspire and complement each other. This begins with a rationale for the existence of non-human aesthetics, followed by an overview of existing research into non-human aesthetic dimensions. Novel aesthetic categories are proposed and the challenge of how to include non-human aesthetic sensibility in design is discussed.