Description

Background Virtual Reality (VR) refers to a computer-generated digital environment that can be experienced and interacted with as if that environment were real. VR systems are typically classified as immersive, semi-immersive, or non-immersive, with immersion referring to the level of user perception with regard to being in a virtual environment (VE) rather than the real world: immersive VR systems supply VEs with a changing field of view via head-mounted displays, and in which movement is achieved via hardware such as head trackers, hand controllers, and body motion sensors; semi-immersive VR refers to systems that use projection-based systems (e.g., driving simulators and use of shutter glasses); non-immersive VR systems include basic desktop displays and videogames.

Considerable evidence exists for using VR for rehabilitation of acquired brain injury (ABI), with a particular focus on stroke. The benefits of VR for ABI rehabilitation seem to include enhanced ecological validity, the ability to maintain experimental control over assessment and treatment standardization, and the control of task complexity. Indeed, VR can provide relatively naturalistic VEs for repeated practice of functional tasks such as activities of (instrumental) daily living which may assist with generalizing targeted skills. VR can also enhance patient motivation and active participation thanks to visual and auditory feedback, which is necessary for neurorehabilitation. Furthermore, VR tools offer the possibility to adapt the exercises to the patient's capabilities and needs and monitor their performance.

However, to date very little evidence has been collected in patients with ABI with different aetiologies (i.e., traumatic or anoxic brain injury) and level of severity (i.e., sABI). Moreover, current evidence provides some support for using VR for ABI rehabilitation, but the quality of the evidence is relatively low, and many studies include non-immersive and semi-immersive systems rather than focusing on immersive VR technology. For instance, a recent study44 investigated the effects of non-immersive VR-based training to improve executive abilities in patients with moderate to severe traumatic brain injury (TBI). Executive dysfunction is among the most common facets of cognitive impairment following TBI, involving about 48% of moderate-to-severe TBI patients. Patients received either the standard cognitive training (i.e., paper and pencil) or the VR-based cognitive training. The authors found that all patients improved their global cognitive and executive function, even though those treated with VR achieved better outcomes44. Although this study showed that VR cognitive rehabilitation can be a promising tool to improve executive functions, further studies are needed to confirm the value of VR in sABI. The present multicentre study aims to overcome current literature issues as heterogeneity of populations and outcomes, small sample sizes and a lack of randomized controlled trials, which can affect the level of evidence and generalizability of results.

Methods Study type: interventional Allocation: randomized Intervention model: parallel assignment (1:1) 28 patients will be randomly assigned to receive either 30 minutes of VR or TCT sessions at the same time each day throughout the experiment. 20 VR or TCT sessions will be applied, 5 per week for 5 weeks. Both groups will receive an additional 60 minute-comprehensive daily rehabilitation programme in the 3 months of the study. This programme consists of active limb mobilization, training on different cognitive domains, occupational therapy, language and swallowing therapy based on the patient's functional condition.

Primary endpoint

-B-A score of the Trail Making Test (TMT) according to normative data adjusted for age and education (Siciliano et al., 2019).

Secondary endpoints

• Total score on the Disability Rating Scale;
• System usability scale (SUS) for evaluating the Usability of VR in patients and professionals;
• modified Barthel Index (mBI) for functional disability. Exploratory endpoints T-otal score on the Italian version of the NeuroPsychiatric Inventory;
• Quantitative EEG;
• Blood biomarkers (BDNF, NFL, GFAP);
• Level of Cognitive Functioning;
• Total score on the Galveston Orientation and Amnesia Test;
• Scores on the Broken Hearts task (overall accuracy) and/or Trails task (baseline and shifting scores) on the Italian version of the Oxford Cognitive Screening.

Adverse Events Report: emptiness/disorientation, nausea/feeling of emptiness, headache, disorientation, dizziness, tremors/nausea/blurred vision/dizziness, nausea, vertigo and sense of unreality) will also be collected weekly in both groups from enrolment through termination of study protocol.