Immersive Virtual Reality in Mechanically Ventilated Patients

Delirium Clinical Trial

Official title: Safety, Tolerability, and Early Efficacy of Immersive Virtual Reality for Early Neurocognitive Stimulation in the Intensive Care Unit.

Status Recruiting

Clinical Trial Summary

New or worsening cognitive impairment occurs in up to 58% of survivors of critical illnesses and are long-lasting with significant disability and socioeconomic cost. There are currently no known interventions that reduce the incidence of cognitive impairment after critical illnesses. Immersive Virtual Reality (IVR) is the use of technology to create a perception of presence in a three-dimensional, computer-generated interactive simulated environment. Prior clinical studies have demonstrated potential efficacy in rehabilitation of severe traumatic brain injury.

The investigators propose a preliminary study for the evaluation of safety, tolerability, and early efficacy of immersive virtual reality for early neurocognitive stimulation in critically-ill, mechanically ventilated patients. The investigators hypothesize that the use of IVR technology for early neurocognitive simulation is safe and tolerable in these patients. This study will also evaluate whether early application of IVR in critically ill, mechanically ventilated subjects, can provide neurocognitive stimulation.

30 patients admitted to the intensive care unit for acute respiratory failure or septic shock will be evaluated for recruitment. 10 patients will be in the control group and 20 patients would have 2 sessions of IVR planned daily for a maximum of 3 days. Assessment of safety will involve monitoring for physiological derangements in heart rate, respiratory rate, pulse oximetry and blood pressure during the IVR session. Assessment of tolerability will involve monitoring for increased agitation. Assessment of early efficacy will involve evaluation of visual attention during the IVR session. 5-channel electroencephalogram would aim to detect objective changes in visual event-related potentials and the IVR headgear will incorporate eye-tracking technology.

To conclude, should IVR be feasible and safe, future interventional studies may be planned to investigate its impact on reduction in the use of sedatives, analgesia, delirium incidence and severity of cognitive impairment associated with critical illness.

Clinical Trial Description

Advancements in the last 2 decades in the field of critical care medicine has led to an improvement in mortality of critically ill patients. This has led to interest in the long-term functional disabilities that the survivors suffer. The risks of developing cognitive dysfunction after critical illness has been associated with older age, longer duration of critical illness, hyperglycaemia, prolonged use of sedatives and analgesia, as well as delirium. The BRAIN-ICU study reported that in adults with respiratory failure and shock, the incidence of cognitive impairment at 1 year was 34% for 1.5 SD below population mean (similar to moderate traumatic brain injury) and 24% for 2.5 SD below population mean (similar to mild Alzheimer's disease). Some proposed mechanisms include cerebral hypoxia secondary to respiratory failure, cerebral inflammation and neuronal apoptosis related to sepsis, and prolonged disruption of sleep cycles. Neuronal imaging such as diffusion-tensor MRI during critical illness show diffuse hyperintense white matter changes and subsequent distant imaging studies show generalised cerebral atrophy.

Critical care societies have endorsed the use of care bundles for pain, agitation and delirium management. Few specialised centres with dedicated survivor clinics evaluate functional impairment via diagnostic investigations, physical, neurological examinations and psychological assessments, to provide personalised rehabilitation. While these initiatives have been shown to improve patient satisfaction, quality of transitional care and reduction of inappropriate emergency room visits, there are no definitive interventions that have improved cognitive outcomes.

Psychiatric co-morbidities of anxiety, depression and post-traumatic stress disorder(PTSD) have been shown to be associated with delirium and cognitive impairment after critical illness. Survivor accounts revealed a mixture of delusional and factual memories resulting in the distortion of experiences. Intensive care diaries involve the recording of significant daily events and is an attempt at systematic reconstruction of memories by medical staff, family and friends. This has been shown to reduce the incidence of PTSD after critical illness. It raises the possibility that incidence of cognitive impairment, too, may be reduced with non-pharmacological methods.

An intensive care admission involves the immersion of a patient in a foreign environment that is dominated by machines, the use of esoteric language by medical staff and persistent sleep disruption that combines deprivation of meaningful sensory stimulation with noxious sensory overload of alarms and lights. There is an unmet need for the provision of a calm, familiar environment, and deliberate neurocognitive simulation with the intention of allowing processes of thought, reasoning, memory and imagination to occur as they do in everyday life. Allowing these cognitive processes to occur may reduce the use of sedatives, delirium occurrence, and possibly cognitive impairment. Cognitive impairment after critical illness is known to decrease the rehabilitation potential of survivors, increase caregiver burden and is associated with higher utilisation of long-term healthcare resources. There is a need for interventional clinical studies that address prolonged cognitive impairment after critical illnesses.

The overall aim of the study is to improve clinical outcomes in critically ill and mechanically ventilated patients.

The primary hypothesis is that the use of an immersive virtual reality headset for early neurocognitive stimulation in critically ill, mechanically ventilated patients is safe and well tolerated (i.e., does not result in significantly increased agitation).

The primary outcome of the study would be the composite endpoint of both safety and tolerability. The immersive VA is considered as safe and tolerable if the patient does not experience any safety or tolerability events. In both arms, subjects who complete of 4 out of 4 to 6 planned sessions would be considered as having met criteria for both safety and tolerability. If 3 or less sessions were initiated, completion of 2 or more sessions would be considered for having met criteria for both safety and tolerability. The IVR intervention would be considered safe and tolerable if the difference in composite endpoint in the intervention arm is not 20% more than the control arm.

Demonstration of safety, defined as the non-occurrence of significant physiological events that require early termination of the IVR session. The use of an iVR is safe and does not cause physiological changes that require the termination of more than 2 out of 6 planned interventions.

Demonstration of tolerability, defined as: the occurrence of the event that the Richmond Agitation-Sedation Score (RASS) greater than or equal to +2 during the use of the immersive virtual reality headset and for the immediate 15 minutes after completion. The RASS score, ranging from -5 to +4, is a validated scoring system used by clinical staff to evaluate the degree of sedation and agitation of mechanically ventilated patients. A score of +2 reflects an agitated state that is characterised by frequent non-purposeful movement or presence of patient-ventilator dys-synchrony. Each subject has 6 planned interventions, completion of 4 out of 6 interventions would be considered demonstration of tolerability.

There are 2 secondary aims in this study to demonstrate early efficacy in terms of neurocognitive stimulation. One would be comparing change in the EEG data after the immersive VR sessions from the baseline, that may indicate visual attention. The hypothesis is that visual attention during the intervention can be demonstrated with EEG waveforms. The other secondary aim will be evaluation of the eye-tracking software as a potential tool for meaningful interaction. ;

Related Conditions & MeSH terms

• Delirium
• Mechanical Ventilation
• Virtual Reality

• NCT number: NCT03569358
• Study type: Interventional
• Source: Changi General Hospital
• Contact: Jessica LS Quah, M.B.B.S.
• Phone: 65-67888833
• Email: jessica_quah@cgh.com.sg
• Status: Recruiting
• Phase: N/A
• Start date: July 2, 2018
• Completion date: July 2, 2019