Introduction
Metaverse and healthcare
Metaverse and urology
Methods
From telemedicine to virtual consultations and virtual offices
References | Topic | Preclinical/clinical (n. of patients) | Description of application |
---|---|---|---|
Kye [1] | Metaverse definition | Preclinical | 4 types of metaverse description |
Smart [2] | Metaverse definition | Preclinical | Metaverse definition starting from web 2.0 |
Han [3] | Metaverse definition | Preclinical | Explore typologies of virtual world |
Dwidedi [4] | Metaverse definition | Preclinical | Metaverse impact in real life |
Bhugaonkar [13] | Metaverse definition | Preclinical | How Metaverse can promote innovative medical education, surgery, medical treatment, and online health management |
Calvillo-Arbizu [12] | Metaverse definition | Preclinical | Explore application of IoT in healthcare |
Gallagher [8] | Surgical training and education | Preclinical | Integration of VR training into a surgical training program |
Nagendran [9] | Surgical training and education | Preclinical | Assess benefits and harms of supplementary virtual reality training of surgical trainees |
Panait [10] | Surgical training and education | Preclinical | Developing of a laparoscopic skills curriculum based on a virtual reality simulator |
Cevallos [11] | Surgical training and education | Preclinical | To examine the efficacy of VR to prepare surgical trainees for a pediatric orthopedic surgery procedure |
Lungu [14] | Surgical training and education | Preclinical | Comprehensive overview of the application of VR, AR and MR for distinct surgical disciplines |
Kim [15] | Surgical training and education | Preclinical | Investigate the state-of-the-art VR/AR technology relevant to plastic surgery |
Novara [5] | Telehealth | Clinical (n. Pts = 34,350) | Telehealth in Urology: review of literature Telemedicine has been adopted successfully in selected patients with several common clinical urological conditions |
Garfan [16] | Telehealth | Clinical (n/a) | Review of telehealth literature comprehensively since the pandemic started Need for establishing clear rules for telemedicine and regulations by governments and health organizations |
Hatcher-Martin [17] | Telehealth | Clinical (n/a) | To determine potential cost-savings and patient acceptance of telemedicine A large number of patients want to participate in outpatient teleneurology visits |
Russo [18] | Telehealth | Clinical (n. Pts = 5695) | Quantify money savings by adopting telemedicine in Veterans Affairs healthcare Telemedicine at the VA saves travel distance and time |
Scott Kruse [19] | Telehealth | Clinical (n/a) | Evaluate barriers to adopting telemedicine worldwide through the analysis of published work Top barriers are technology specific and could be overcome through training and change management techniques |
Alemayehu [20] | Telehealth | Preclinical | Opportunity with virtual or digital clinical trials in offering diverse patients easier and attractive means to participate in clinical trials |
Inan [21] | Telehealth | Preclinical | Current state of the art for digital clinical trials |
Skalidis [22] | Telehealth Education | Preclinical | Enhancing medical visits, assisting cardiovascular interventions, and reshaping the way medical education |
Pandrangi [23] | Patient’s education | Clinical (n. Pts = 19) | Use of a 3D model of an abdominal aorta aneurysm to view in VR and so assess the use of VR in patient education VR proved to be an engaging learning tool that patients perceived as beneficial in understanding their health status |
Gold [24] | Pain management | Clinical (n. Pts = 20) | Test the efficacy and suitability of virtual reality (VR) as a pain distraction for pediatric intravenous (i.v.) placement VR pain distraction was positively endorsed by all reporters and is a promising tool for decreasing pain, and anxiety in children undergoing acute medical interventions |
Gold [25] | Pain management | Clinical (n/a) | Review of current literature on state-of-the-art pain distraction and future directions in VR VR pain distraction has become increasingly affordable, and initial research has demonstrated its efficacy for decreasing pain, anxiety, and fear |
Furman [26] | Pain management | Clinical (n. Pts = 38) | Analgesic effect of immersive virtual reality (VR) during periodontal scaling and root planning (SRP) procedures Use of immersive VR distraction may be an effective method of pain control during SRP procedures |
Schneider [27] | Pain management | Clinical (n. Pts = 137) | Predicting the difference between actual time elapsed during receipt of intravenous chemotherapy while immersed in a VR environment vs patient’s retrospective estimates of time elapsed VR is a non-invasive intervention that can make chemotherapy treatments more tolerable |
Morris [28] | Pain management | Clinical (n/a) | Review evidence for the effectiveness of VR on reducing pain and anxiety in burn injury patients undergoing wound dressing changes and physiotherapy management VR could help manage burn pain and improve burn patient rehabilitation |
Li [29] | Pain management | Preclinical | Exploring clinical and experimental applications of VR for acute and chronic pain management |
Pourmand [6] | Pain management | Clinical (n. Pts = 460) | Virtual reality (VR) therapies as a clinical tool for acute and chronic pain Virtual reality can distract patients to reduce pain and anxiety |
Vianez [30] | Rehabilitation | Clinical (n. Pts = 22) | Virtual reality exposure therapy (VRET) as an emerging treatment for people diagnosed with Post-Traumatic Stress Disorder (PTSD) Findings suggest VRET as a co-creation process, which requires more controlled, personalized, and in-depth research on its clinical applicability |
Botelho [31] | Rehabilitation | Clinical (n. Pts = 46) | Pelvic floor muscle (PFM) training program designed as a virtual reality intervention program This virtual reality program promoted an increase in PFM contractility and a decrease in postmenopausal urinary symptoms |
Carl [32] | Rehabilitation | Clinical (n. Pts = 1057) | Investigate efficacy of trials of virtual reality exposure therapy (VRET) for anxiety-related disorders VRET is an effective and equal medium for exposure therapy |
Pires [7] | “Metaverse-assisted” surgery | Preclinical | Focus on VR as an alternative to slice-based medical analysis workstations |
Profeta [33] | “Metaverse-assisted” surgery | Preclinical | Role of AR in relation to sentinel lymph node biopsy |
Khor [34] | “Metaverse assisted” surgery | Preclinical | Introduction to the technology and the potential areas of development in the surgical arena of AR and VR |
Jiang [35] | “Metaverse assisted” surgery | Preclinical | 3D AR navigation method with point cloud-based image–patient registration to merge virtual images in the real environment for dental implants using a 3D image overlay |
Vávra [36] | “Metaverse assisted” surgery | Preclinical | This review evaluates whether augmented reality can presently improve the results of surgical procedures |
Pérez-Pachón [37] | “Metaverse assisted” surgery | Clinical (n/a) | Explore which existing tracking and registration methods and technologies allow healthcare professionals to develop and implement these systems in-house Need for more procedure-specific experiments with a sufficient number of subjects and measurements and including data about surgical outcomes and patients' recovery |
Roberts [38] | “Metaverse assisted” surgery | Clinical (n/a) | Advance in the use of AR for improvements in urologic outcome Advances in AR have led to increasing registration accuracy as well as increased ability to identify anatomic landmarks and improve outcomes during urologic procedures such as RARP and robot-assisted partial nephrectomy |
Onggirawan [39] | Surgical training and education | Preclinical | Using Metaverse in the form of virtual space in the educational field and how teachers and students respond to the process |
Tan [40] | Virtual meetings | Preclinical | Creation of virtual environments with three-dimensional (3D) space and avatar |
Kostick-Quenet [41] | Cybersecurity | Preclinical | Non-fungible tokens (NFTs) can help incentivize a more democratized, transparent, and efficient system for health information exchange in which patients participate in decisions about how and with whom their personal health information is shared |
Jones [42] | Cybersecurity | Preclinical | NFTs definition and their use by scientists |
Field of application | Pros | Cons |
---|---|---|
Virtual consultations | Reach rural areas, decrease time, and cost of visits | Elderly people not used to technology, cost of technology |
Training and education | Learning anatomy in 3D, immersive surgical training, virtual congresses | Cannot replace real-life practice |
Pain management | Deep immersion and reduction in opioid usage | Lack of evidence on long-term benefits |
Surgical planning | 3D anatomical modeling and procedure simulation | How well can models reproduce reality and intraoperative complications? |
Rehabilitation | Improve adherence to exercise, reduce anxiety and promote well-being | Could generate dissociation from reality |
Research | Virtual clinical trials | Not always possible (i.e., medical procedures or need for visit) |
Meetings | Virtual meetings | Absence of human contact |