Awareness Detection and Communication in Disorders of Consciousness

Not Applicable

Recruiting

• Conditions: Disorder of Consciousness; Motor Neuron Disease; Stroke; Paralysis; Physical Disability
• Interventions: Other: Motor imagery based EEG-BCI

• Registration Number: NCT03827187
• Lead Sponsor: University of Ulster

Brief Summary

STUDY OVERVIEW Brain injury can result in a loss of consciousness or awareness, to varying degrees. Some injuries are mild and cause relatively minor changes in consciousness. However, in severe cases a person can be left in a state where they are "awake" but unaware, which is called unresponsive wakefulness syndrome (UWS, previously known as a vegetative state). Up to 43% of patients with a UWS diagnosis, regain some conscious awareness, and are then reclassified as minimally conscious after further assessment by clinical experts. Many of those in the minimally conscious state (MCS) and all with unresponsive wakefulness syndrome (UWS) are incapable of providing any, or consistent, overt motor responses and therefore, in some cases, existing measures of consciousness are not able to provide an accurate assessment. Furthermore, patients with locked-in syndrome (LIS), which is not a disorder of consciousness as patients are wholly aware, also, struggle to produce overt motor responses due to paralysis and anarthria, leading to long delays in accurate diagnoses using current measures to determine levels of consciousness and awareness. There is evidence that LIS patients, and a subset of patients with prolonged disorders of consciousness (DoC), can imagine movement (such as imagining lifting a heavy weight with their right arm) when given instructions presented either auditorily or visually - and the pattern of brain activity that they produce when imagining these movements, can be recorded using a method known as electroencephalography (or EEG). With these findings, the investigators have gathered evidence that EEG-based bedside detection of conscious awareness is possible using Brain- Computer Interface (BCI) technology - whereby a computer programme translates information from the users EEG-recorded patterns of activity, to computer commands that allow the user to interact via a user interface. The BCI system for the current study employs three possible imagined movement combinations for a two-class movement classification; left- vs right-arm, right-arm vs feet, and left-arm vs feet. Participants are trained, using real-time feedback on their performance, to use one of these combinations of imagined movement to respond to 'yes' or 'no' answer questions in the Q\&A sessions, by imagining one movement for 'yes' and the other for 'no'. A single combination of movements is chosen for each participant at the outset, and this participant-specific combination is used throughout their sessions. The study comprises three phases. The assessment Phase I (sessions 1-2) is to determine if the patient can imagine movements and produce detectable modulation in sensorimotor rhythms and thus is responding to instructions. Phase II (sessions 3-6) involves motor-imagery (MI) -BCI training with neurofeedback to facilitate learning of brain activity modulation; Phase III (sessions 7-10) assesses patients' MI-BCI response to closed questions, categorized to assess biographical, numerical, logical, and situational awareness. The present study augments the evidence of the efficacy for EEG-based BCI technology as an objective movement-independent diagnostic tool for the assessment of, and distinction between, PDoC and LIS patients.

Detailed Description

PRINCIPLE RESEARCH QUESTIONS The project will address a number key principal research questions largely based on two phases to the study.

Phase/study 1

1. What percentage of disorder of consciousness patients assessed provide evidence of awareness using EEG-based BCI technology?

2. How does this differ from their clinical diagnosis/prognosis?

3. Does the EEG-based information complement or augment the clinical assessment and diagnosis process?

4. Do any of those participants who are diagnosed as being in a vegetative state (or MCS) show signs of awareness beyond the vegetative state based on the EEG-based detection of awareness protocol?

Phase/study 2

1. Is it possible to train those participants who show clear signs of awareness, as indicated by significant brain activation during the initial assessment in study 1, to produce a more prominent and/or consistent response over a number of training sessions using BCI based training and feedback protocols?

2. Can a subset of the participants use BCI technology to communicate simple responses to questions at the end of the study or is there enough evidence to suggest that with further training over a longer period that the participant may use BCI technology as an alternative or an exclusive communication channel?

3. Does neurotechnology offer any other therapeutic benefits to patients, for example, a means of technology interaction that is movement independent and engaging brain areas otherwise not engaged?

SECONDARY RESEARCH Q UESTIONS

1. Does the technology aid feedback/interpretation on assessment outcomes from consultants?

2. How might the experiment provide an opportunity for training others in the deployment of the technology in a clinical setting?

3. What types of BCI methods of feedback are best auditory/visual or both, musical or broadband noise, games or applications etc?

Study Timeline

• Study First Submitted: 2018-09-05
• Study First Submitted QC: 2019-01-30
• Study First Posted: 2019-02-01
• Study Start: 2022-02-08
• Status Verified: 2024-11
• Last Update Submitted: 2024-12-09
• Last Update Posted: 2024-12-13
• Primary Completion: 2026-08
• Study Completion: 2026-08

Recruitment & Eligibility

• Status: RECRUITING
• Sex: All
• Target Recruitment: 30

Inclusion Criteria

• Disorder of consciousness or low awareness state diagnosis ranging from unclear diagnosis in low awareness states, vegetative state and minimally conscious diagnosis. Those with locked in syndrome / completed locked in syndrome resulting from injury or disease e.g., motor neuron disease who do not have health problems that would preclude them from participating may be assessed but considered as a separate cohort to those with low awareness states.
• acute, post-acute patients where appropriate

Exclusion Criteria

• Participants with brain related diseases or illnesses (e.g., progressive neurological condition or uncontrolled epilepsy) or suffer from pain (these may adversely affect the brain data produced) and are deemed to be unsuitable for the trials by clinical teams.
• Current consumption of medications that cause excessive fatigue or adversely affect cognitive functioning
• Where English is not the individual's first language
• Participant with excessive uncontrollable arm or head movement or teeth grinding as EEG signal quality will be degraded significantly.

Study 2 - BCI training

Inclusion Criteria:

• Those identified in study 1 to have a level of awareness based on observed appropriate brain activations and/or those who have known awareness but are target groups for movement independent assistive devices and technologies controlled using a brain-computer interface.

Exclusion Criteria:

• Participants who have shown no active brain responses in study 1 where the difference between baseline

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: SINGLE_GROUP

Arm && Interventions

Group	Intervention	Description
Motor imagery based Brain computer interfacing	Motor imagery based EEG-BCI	Brief assessment of motor imagery in response to command, auditory feedback training and responding to binary yes-no closed questions through Electroencephalography based Brain-computer interfacing.

Primary Outcome Measures

Name	Time	Method
Change in performance accuracy of BCI use pre- and post- training	~10 sessions of ~1.5 hours	The main primary outcome measure is BCI performance (e.g., accuracy in % for repeated binary choice selections using the BCI e.g., movement free control of cursor towards one of two targets using EEG-based BCI or accuracy in discriminating different brain responses associated with imagined movement of different limbs.; Multiple cross validation will be performed to assess the significance of the difference between a baseline accuracy (pre cue- where accuracy in the response is expected to be around 50% (chance level)) and the peak accuracy (where the accuracy of discriminating event related brain response peaks following the cue).
Change in ability to use imagined movements to consistently communicate yes-no responses to closed questions over multiple sessions by participant with Prolonged Disorder of Consciousness	3-4 sessions of ~1.5 hours	Accuracy rate when using the BCI system to provide known responses to statements will be used to build evidence to establish that participants could use the technology as an aided communication method. Examples of questions are given below.; Yes Questions: Your name is David. You are 25 years old.

Secondary Outcome Measures

Name	Time	Method
Changes in Wessex Head Injury Matrix and Coma Recovery Scale Scores due to potential therapeutic benefit of engaging in motor imagery	~10 sessions of ~1.5 hours	Is there a benefit to intentionally modulating motor cortex regions in response to a command in a timed paradigm over multiple sessions. In participants with a Prolonged Disorder of Consciousness the scores for The Wessex Head Injury Matrix and Coma-Recovery Scale Revised taken at each session will be looked at to seek out therapeutic benefit. Here therapeutic benefit is defined in terms of changes in state of arousal and awareness of self/environment. Therapeutic benefit may also be assessed via performance given as an accuracy percentage of motor imagery trials successfully completed, and how this changes over time.
Change in performance accuracy as a factor of whether feedback was presented as music or broadband noise,	~10 sessions of ~1.5hours	Is there a significant difference in performance as a function of type of feedback participant was receiving - music clips or broadband noise.
Changes in performance accuracy as a results of time of day of research experimentation	~10 sessions of ~1.5hours	Arousability varies with time of day - is this reflected in BCI use performance or do some patients perform more optimally at a particular time? The aim is to perform 5 sessions in the morning and 5 in the afternoon to look at the affects of time of day.
Diagnostic utility of BCI data provided through study completion to clinicians	2 - 7 weeks. Duration of study which lasts 10 sessions of ~1.5 hours in addition to some time for analysis/reporting of results	The performance accuracy of the participant in producing consistent cue- induced imagined movements appropriately in timed paradigms will be assessed across sessions, to determine variability and consistency in performance accuracy. The affects of real-time feedback will be looked at, alongside differences in performance accuracy across question subcategories. Performance accuracy per question subcategory will be assessed to evaluate awareness of self versus awareness of environment and understanding of numbers and letters, and logic.; Whether this information is in line with the patient's current diagnosis/CRS-R and WHIM scores will be assessed in order to further understand whether the technology can aid feedback/interpretation on assessment outcomes from consultants?

Trial Locations

Locations (18)

NHS Lothian; 🇬🇧 Edinburgh, United Kingdom

Castel Froma Neuro Care; 🇬🇧 Warwick, Warwickshire, United Kingdom

National Rehabilitation Hospital of Ireland; 🇮🇪 Dublin, Ireland

Northern Health and Social Care Trust; 🇬🇧 Antrim, United Kingdom

Barnsley Hospital NHS Foundation Trust; 🇬🇧 Barnsley, United Kingdom

Frenchay Brain Injury Rehabilitation Centre; 🇬🇧 Bristol, United Kingdom

The Walton Centre NHS Foundation Trust; 🇬🇧 Liverpool, United Kingdom

Western Health and Social Care Trust; 🇬🇧 Londonderry, United Kingdom

Imperial College Healthcare NHS Trust; 🇬🇧 London, United Kingdom

Oxford University Hospitals NHS Foundation Trust; 🇬🇧 Oxford, United Kingdom

Royal Hospital for Neuro-Disability; 🇬🇧 London, United Kingdom

The Huntercombe Group; 🇬🇧 London, United Kingdom

Sheffield Teaching Hospitals NHS Foundation Trust; 🇬🇧 Sheffield, United Kingdom

Southern Health and Social Care Trust; 🇬🇧 Portadown, United Kingdom

Inspire Neurocare Worcester; 🇬🇧 Worcester, United Kingdom

South Warwickshire NHS Foundation Trust; 🇬🇧 Warwick, United Kingdom

Belfast Health and Social Care Trust; 🇬🇧 Belfast, United Kingdom

Hull University Teaching Hospitals NHS Trust; 🇬🇧 Hull, United Kingdom