BioVR: a platform for virtual reality assisted biological data integration and visualization

Zhang, Jimmy F.; Paciorkowski, Alex R.; Craig, P.; Cui, Feng

doi:10.1186/s12859-019-2666-z

Cited by 40 publications

(39 citation statements)

References 29 publications

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“…This technology plays a useful role to improve the performance of the medical field. 27,28 It is a useful and practical technology to increase the satisfaction of trainee and the patient. This technology provides an appropriate solution using its process in the medical field, as shown in Fig.…”

Section: Process Of Adoption Of Vr In the Medical Fieldmentioning

confidence: 99%

Virtual reality applications toward medical field

Javaid

Haleem

2020

Clinical Epidemiology and Global Health

173

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Background/objectives: Virtual Reality (VR) is a developing technology, which seems to have extensive applications in different areas such as entertainment, sports, gaming and simulation. In the current scenario, due to Computer-generated imagery and content aim at simulating a real presence through senses capability, it has functional applications in the medical field. So, there are requirements to study its applicability in the medical field. Methods: Relevant papers on VR in the context of the medical field are identified and studied. This paper is a literature review based analysis, where we are trying to find how this technology is going to solve a medicalrelated problem in saving the life of the patient and what are the significant applications. Results: VR provides a simulated environment to interact with the 3D world. Medical professionals are developing and implementing this technology for training, diagnosis and virtual treatment during a critical situation. The study sees that there is good potential for VR in the medical field. We also studied the processes involved in implementing this technology in the medical field. Finally, this paper identifies fourteen major applications of VR in the medical field with description. This technology is helping to create quality healthcare services during complicated cases. Conclusions: VR is used effectively for better surgical technique. It creates detailed virtual models of a patient's anatomy. It helps physicians to effectively move around and view virtual 3D images from different angles. This technology is currently applied in cardiology and Neurology for monitoring and improves patient outcomes. It plays a significant role to help physician related to trauma and other fractures. VR is an emerging technology which can also be used in hospitals and clinics for rehabilitation & training approaches. The applications of this technology are in virtual guides and to fulfil different other virtual goals in the medical field. It seems like an efficient technology to teach body fitness and help create a positive impact on doctors and the patient. This technology leads to creative and exciting discoveries in the medical field.

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Section: Process Of Adoption Of Vr In the Medical Fieldmentioning

confidence: 99%

Virtual reality applications toward medical field

Javaid

Haleem

2020

Clinical Epidemiology and Global Health

173

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“…Processing larger molecules requires the command-line version and its four dependencies: PyMOL [3], Blender [38], Open Babel [40], and Molconvert (ChemAxon). Many other VR and AR approaches for molecular visualization involve similarly challenging software pipelines [19,21,41]. In contrast, ProteinVR requires no download or dependencies and so is more accessible.…”

Section: Comparison With Other Programsmentioning

confidence: 99%

ProteinVR: Web-based molecular visualization in virtual reality

et al. 2020

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Protein structure determines biological function. Accurately conceptualizing 3D protein/ ligand structures is thus vital to scientific research and education. Virtual reality (VR) enables protein visualization in stereoscopic 3D, but many VR molecular-visualization programs are expensive and challenging to use; work only on specific VR headsets; rely on complicated model-preparation software; and/or require the user to install separate programs or plugins. Here we introduce ProteinVR, a web-based application that works on various VR setups and operating systems. ProteinVR displays molecular structures within 3D environments that give useful biological context and allow users to situate themselves in 3D space. Our web-based implementation is ideal for hypothesis generation and education in research and large-classroom settings. We release ProteinVR under the open-source BSD-3-Clause license.

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“…An innovation in technology that is being applied to large genomic datasets is virtual reality (VR). VR applications have been created for several subfields of biology and genetics, including visualization of synteny [6], tracing of neural pathways [7], or three-dimensional protein structure [8][9][10]. These visualizations exist natively in a three-dimensional environment, making them ideal candidates for exploration in virtual reality.…”

Section: Introductionmentioning

confidence: 99%

“…One drawback to VR-based visualizations is that creation of the visualization requires a combination of multiple skills. These visualizations are typically created using either WebXR in HTML [6] or an application framework such as Unity or Unreal Engine [8,10], requiring considerable programming experience. Additionally, VR equipment is not yet widely deployed, meaning its availability to researchers may be limited.…”

Section: Introductionmentioning

confidence: 99%

BigTop: a three-dimensional virtual reality tool for GWAS visualization

2020

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Background: Genome-wide association studies (GWAS) are typically visualized using a two-dimensional Manhattan plot, displaying chromosomal location of SNPs along the x-axis and the negative log-10 of their p-value on the yaxis. This traditional plot provides a broad overview of the results, but offers little opportunity for interaction or expansion of specific regions, and is unable to show additional dimensions of the dataset. Results: We created BigTop, a visualization framework in virtual reality (VR), designed to render a Manhattan plot in three dimensions, wrapping the graph around the user in a simulated cylindrical room. BigTop uses the z-axis to display minor allele frequency of each SNP, allowing for the identification of allelic variants of genes. BigTop also offers additional interactivity, allowing users to select any individual SNP and receive expanded information, including SNP name, exact values, and gene location, if applicable. BigTop is built in JavaScript using the React and A-Frame frameworks, and can be rendered using commercially available VR headsets or in a two-dimensional web browser such as Google Chrome. Data is read into BigTop in JSON format, and can be provided as either JSON or a tab-separated text file. Conclusions: Using additional dimensions and interactivity options offered through VR, we provide a new, interactive, three-dimensional representation of the traditional Manhattan plot for displaying and exploring GWAS data.

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BioVR: a platform for virtual reality assisted biological data integration and visualization

Cited by 40 publications

References 29 publications

Virtual reality applications toward medical field

Virtual reality applications toward medical field

ProteinVR: Web-based molecular visualization in virtual reality

BigTop: a three-dimensional virtual reality tool for GWAS visualization

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