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Canadian Perspectives on the Clinical Actionability of Neuroimaging in Disorders of Consciousness

Published online by Cambridge University Press:  25 March 2015

Grace Lee ,
Adrian C. Byram ,
Adrian M. Owen ,
Urs Ribary ,
A. Jon Stoessl ,
Andrea Townson ,
Christine Stables  and
Judy Illes
Grace Lee
Affiliation:
National Core for Neuroethics, Division of Neurology, Department of Medicine, University of British Columbia, Vancouver, Canada
Adrian C. Byram
Affiliation:
National Core for Neuroethics, Division of Neurology, Department of Medicine, University of British Columbia, Vancouver, Canada
Adrian M. Owen
Affiliation:
The Brain and Mind Institute, University of Western Ontario, London, Canada
Urs Ribary
Affiliation:
Behavioural and Cognitive Neuroscience Institute, Simon Fraser University, Burnaby, Canada
A. Jon Stoessl
Affiliation:
National Core for Neuroethics, Division of Neurology, Department of Medicine, University of British Columbia, Vancouver, Canada Pacific Parkinson’s Research Centre and National Parkinson Foundation Centre of Excellence, Vancouver, Canada
Andrea Townson
Affiliation:
Division of Physical Medicine and Rehabilitation, Department of Medicine, Faculty of Medicine, University of British Columbia, Vancouver, Canada
Christine Stables
Affiliation:
Pacific Parkinson’s Research Centre and National Parkinson Foundation Centre of Excellence, Vancouver, Canada
Judy Illes*
Affiliation:
National Core for Neuroethics, Division of Neurology, Department of Medicine, University of British Columbia, Vancouver, Canada
*
Correspondence to: Judy Illes, Canada Research Chair in Neuroethics, Professor of Neurology, Faculty of Medicine, University of British Columbia, 2211 Wesbrook Mall, Koerner S124, Vancouver, BC, Canada V6T 2B5. Email: jilles@mail.ubc.ca
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Abstract

Background: Acquired brain injury is a critical public health and socioeconomic problem in Canada, leaving many patients in vegetative, minimally conscious, or locked-in states, unresponsive and unable to communicate. Recent advances in neuroimaging research have demonstrated residual consciousness in a few exemplary patients with acquired brain injury, suggesting potential misdiagnosis and changes in prognosis. Such progress, in parallel with research using multimodal brain imaging technologies in recent years, has promising implications for clinical translation, notwithstanding the many challenges that impact health care and policy development. This study explored the perspectives of Canadian professionals with expertise either in neuroimaging research, disorders of consciousness, or both, on the potential clinical applications and implications of imaging technology. Methods: Twenty-two professionals from designated communities of neuroimaging researchers, ethicists, lawyers, and practitioners participated in semistructured interviews. Data were analyzed for emergent themes. Results: The five most dominant themes were: (1) validation and calibration of the methods; (2) informed consent; (3) burdens on the health care system; (4) implications for the Canadian health care system; and (5) possibilities for improved prognosis. Conclusions: Movement of neuroimaging from research into clinical care for acquired brain injury will require careful consideration of legal and ethical issues alongside research reliability, responsible distribution of health care resources, and the interaction of technological capabilities with patient outcome.

Résumé

Perspectives canadiennes à propos de l’ « actionnabilité » clinique de la neuroimagerie dans les troubles de la conscience.Contexte: Une lésion cérébrale acquise est un problème de santé publique et un problème socioéconomique important au Canada et ce type de lésions laisse plusieurs patients dans un état végétatif, de conscience minimale ou de verrouillage avec absence de réponse et incapacité à communiquer. Des progrès récents de la recherche en neuroimagerie ont montré la présence d’un état de conscience résiduel chez quelques patients particuliers ayant subi une lésion cérébrale, ce qui suggère la possibilité qu’un diagnostic erroné ait été posé et donc modifie le pronostic. De tels progrès, en parallèle avec la recherche utilisant des technologies d’imagerie multimodales du cerveau dans les dernières années, comportent des implications prometteuses en clinique malgré les nombreux défis qui ont des incidences sur les soins de santé et l’élaboration de politiques. Cette étude a exploré les perspectives des professionnels Canadiens qui possèdent une expertise, soit dans la recherche en neuroimagerie, dans les troubles de la conscience ou dans ces deux domaines, concernant les applications et les implications cliniques potentielles de la technologie d’imagerie. Méthode: Vingt-deux professionnels de milieux désignés de neuroimagerie, soit des chercheurs, des éthiciens, des avocats et des praticiens ont participé à des entrevues semi-structurées. Les données ont été analysées pour déceler des thèmes émergents. Résultats: Les 5 principaux thèmes émergents étaient les suivants: (1) la validation et la calibration des méthodes; (2) le consentement éclairé; (3) le fardeau pour le système de santé; (4) les implications pour le système de santé canadien; et (5) les possibilités d’améliorer le pronostic. Conclusions: Le transfert de la neuroimagerie des lésions traumatiques cérébrales de la recherche à la clinique requerra qu’on effectue un examen approfondi tant des aspects légaux et éthiques que de la fiabilité de la recherche, de la distribution responsable des ressources en santé et de l’interaction entre les ressources technologiques et les résultats chez les patients.

Keywords

brain injuryneuroethicsneuroimagingTBI (traumatic brain injury)MCS (minimally conscious state)PVS (permanent vegetative state)ethicsqualitative methods
Type
Original Articles
Information
Canadian Journal of Neurological Sciences , Volume 42 , Issue 2 , March 2015 , pp. 96 - 105
Copyright
Copyright © The Canadian Journal of Neurological Sciences Inc. 2015 

Acquired brain injury (ABI), comprising both traumatic brain injury and nontraumatic brain injury such as stroke, anoxia, and infection, is a major cause of death and disability in developed countries. In Canada, more than 40,000 people are hospitalized with an ABI each year, and more than 9% of these patients require posthospitalization rehabilitation.Reference Chen, Bushmeneva, Zagorski, Colantonio, Parsons and Wodchis 1 - Reference Langlois, Rutland-Brown and Wald 3 Some of these patients develop disorders of consciousness (DoC), and remain in a minimally conscious state (MCS), permanent vegetative state (PVS), or locked-in state for years after the original injury.

Using functional magnetic resonance imaging, researchers have detected signals of consciousness in some patients in vegetative statesReference Owen, Coleman, Boly, Davis, Laureys and Pickard 4 , Reference Monti, Vanhaudenhuyse and Coleman 5 who, according to definitions provided by the Multi-Society Task force are typically in the chronic phase of DOC at 3 months after nontraumatic brain damage or 12 months after traumatic brain injury. 6 In these noninvasive brain imaging studies of the hemodynamic correlates of neural processes, researchers have obtained measures of activation profiles similar to uninjured controls attempting to follow verbal commands.Reference Owen, Coleman, Boly, Davis, Laureys and Pickard 4 , Reference Monti, Vanhaudenhuyse and Coleman 5 , Reference Moreno, Schiff, Giacino, Kalmar and Hirsch 7 These efforts have led to new hope for improving patient prognosis and have opened the possibility of communication through the imagery-based paradigm.Reference Monti, Vanhaudenhuyse and Coleman 5 , Reference Fernández-Espejo and Owen 8 , Reference Monti, Coleman and Owen 9 As an example, the popular press reported that Scott Routley, a patient of coauthor Adrian Owen, communicated about his pain via this visualization technique. For more than a decade, Routley was believed to have been in a persistent vegetative state after suffering a severe brain injury in a car accident in 2000.Reference Lunau 10

The possibility of communication, if only to express preferences, has the potential to be of benefit to the patient and a tangible recognition of his or her personhood.Reference Wilkinson, Kahane and Savulescu 11 , Reference Fins 12 Furthermore, rapid advancements in multimodal brain imaging technologies in recent years have contributed to a better understanding of the underlying local and large-scale brain network connectivity and dynamics in healthy and injured brains.Reference Ribary 13 , Reference Ribary, Doesburg and Ward 14 Advanced neuroimaging methods have promising implications to more accurately differentiate between the locked-in state, MCS, and PVS, a differentiation which could be substantially advantageous to these patients and their families given the uncertainty of conventional clinical diagnostic methods.Reference Monti, Coleman and Owen 15 , Reference Coleman, Bekinschtein, Monti, Owen and Pickard 16

These advances raise the possibility of refining the clinical diagnosis of vegetative states, but they also raise questions about the ethical, social, and legal feasibility of translating these research capabilities into clinical practice.Reference Illes, De Vries, Cho and Schraedley-Desmond 17 , Reference Racine and Bell 18 Although evidence of consciousness demonstrated through neuroimaging may improve the accuracy of prognosis, the implications of such findings raise complex questions about withdrawing life-sustaining treatment from brain-injured patients, and further complicate the already elusive definition of consciousness.Reference Wilkinson, Kahane, Horne and Savulescu 19 - Reference Tovino and Winslade 23

Patients’ families and high-profile court cases such as that of Hassan Rasouli, who has been on a ventilator since 2010 when he developed meningitis and severe brain damage after surgery to remove a tumour,Reference Cooper, Chidwick and Sibbald 24 , Reference Dyer 25 create pressures to use such technologies before they are adequately validated. A prudential ethic is needed, therefore, to set boundaries for neuroimaging in the context of clinical decision-making.Reference Lee and Illes 26 Although advances in clinical studies of DoC patients have improved prognostic knowledge and refined diagnostic classifications, evidence to date does not support routine use of functional imaging assessments for all patients, and clinicians need to be prepared to respond to uninformed requests from families for access.Reference Jox, Bernat, Laureys and Racine 27 Fascination with studying impaired consciousness is not new,Reference Koehler and Wijdicks 28 but the more recent and widespread interest in neuroimaging for consciousness highlights the vulnerabilities of families to unrealistic expectations and urges ethical guidance for implementing translational researchReference Racine and Bell 18 , Reference Fins, Illes, Bernat, Hirsch, Laureys and Murphy 29 into clinical practice.

To address these challenges, we explored the views of neuroimaging researchers, practicing physicians, ethicists, and law professors with expertise in neuroimaging, DoC, or both, on the actionability of using neuroimaging to detect signals of consciousness in vegetative patients and its ethical, legal, and social consequences within the Canadian health care environment.

Methods

We used two strategies in series for this qualitative research study. First, we derived a preliminary framework to guide discourse for the Canadian context based on the literature on the subject and the expertise of the contributing authors. Second, on the basis of that framework, we developed the questions for interviews with a range of experts.

All methods involving human subjects were reviewed and approved by the behavioural research ethics board at the University of British Columbia. Written informed consent was obtained from all research participants.

Framework

The framework was designed to guide: (1) the criteria for evaluating the clinical actionability of detecting signals of consciousness in patients diagnosed as vegetative; and (2) the nature and scope of the ethical, social, and legal consequences of making the capability to detect such signals available in Canadian health care. Using methods consistent with a consensus-seeking dialogue,Reference Kvale 30 the process was interpretive and iterative. The authors met face-to-face for the first deliberative session, and then worked in virtual meetings and by email exchange until consensus was reached on a final working framework. The framework organizes the impacts on clinical translation into areas of impact specific to people and institutions.

Interviews

Participant recruitment

The recruitment plan identified potential participants with expertise in DoC from four groups: neuroimaging researchers, practitioners, ethicists, and lawyers from three Canadian academic centres with major programmes of research in neuroimaging. Participants were identified based on a combination of searches on clinical department websites and websites of Canadian neuroimaging research laboratories. Snowball sampling from identified participants increased the overall recruitment pool of eligible participants.

Interview guide

The interview guide consisted of a preamble about the current state of neuroimaging research in DoC, a few questions about the demographic and professional background of the participant, and three content sections with both discrete and open questions. The guide was piloted and vetted among the author team and refined to incorporate feedback.

The first content section focused on clinical actionability criteria. This section included seven open questions about technical challenges, clinical outcomes, and the ethical, social, and legal issues that would be encountered in the clinical use of the technology. The questions are shown in Box 1.

Box 1 Questions in the first section of the interview guide

(1) Describe any technical challenges in detecting signals of consciousness with functional neuroimaging technology.

(2) Do you think this technology could produce a significant change in outcome in terms of patient care, family, or any other aspects?

(3)Would using this technology create ethical concerns? Would these ethical concerns limit its actionability?

(4)Would using this technology create social impacts? Would these social concerns limit its actionability?

(5)Would using this technology create legal concerns? Would these legal concerns limit its actionability?

(6) Would using this technology create economic concerns? Would these economic concerns limit its actionability?

(7) Do you think neuroimaging for disorders of consciousness has the potential to be clinically useful? Timeline for applicability?

This section ended with a final yes/no question to which participants answered whether they thought the technology has potential to be clinically useful overall. If the answer was positive, the interview continued with questions in the second section; if negative, the interview skipped to the third section.

The second section focused on the impact of the technology. This section included 11 questions that probed for the potential impact of the technology on specific groups and institutions: patients, families, and other caregivers; influencers of health and legal policy; communicators of research to professionals and the public; and health care systems.

The third section probed participants about why they were negative about the actionability of the technology—for example, for reasons of technical limitations, ethical concerns, lack of benefit to patients, and socioeconomic concerns. Another question explored whether or not participants perceived any benefits of continuing neuroimaging research. The questions for the second and third sections are shown in Boxes 2 and 3, respectively.

Box 2 Questions in the second section of the interview guide

(1) What is needed before this technology can be used in the clinic?

(2) Assuming that signals of consciousness could be detected in patients:

(A) Would these signals have an impact on patient autonomy:

(i) in terms of the patient’s ability to communicate preferences?

(ii) in terms of the patient’s ability to provide informed consent?

(B) Do you think that signals of consciousness detected by functional neuroimaging could lead to a change in patient prognosis?

(3) Would clinical use of the technology change the way families make decisions for the patient?

(4) Do you think the availability of this neuroimaging technology would have an impact on members of the health care team?

(5) Do you think the nature of health care for these patients will change? How?

(6) What criteria would have to be met before the Canadian health care system would broadly adopt this technology?

(7) What are your views on how this research will impact health care policies around access to health care?

(8) What about its impact on laws concerning competence and consent?

(9) Do you think this research will help us gain new scientific knowledge on brain injury and disorders of consciousness?

(10) How do you think this new knowledge should be communicated?

(11) In your opinion, which imaging modalities are likely to be more fruitful for the application at hand?

(12) I would like to revisit the benchmark questions again to see if you have anything to add to those issues.

Box 3 Questions for the third section of the interview guide

(1) Why not? (To probe why respondents answered negatively to whether they felt neuroimaging for disorders of consciousness has the potential to be clinically useful.)

(2) Do you believe the research will yield any benefits at all?

Data Collection and Analysis

The interviews were conducted by one of the authors (GL), audio recorded, transcribed, imported into NVivo 10 (QSR International) for data management and qualitative analysis. Participants’ names were replaced with alphanumeric codes to protect their confidentiality. Two authors (GL and ACB) independently reviewed transcripts of 7 randomly selected interviews using open coding to identify provisional major themes and subthemes.Reference Boeije 31 , Reference Creswell 32 These major themes and subthemes were used to create a preliminary coding guide, which was then applied to all transcripts in an independent coding process. The same authors conducted several more rounds of independent open coding and reached consensus to expand the coding guide to include primary and secondary level codes. The process was inductive and iterative, and intercoder differences were reconciled by discussion following qualitative methods described by CreswellReference Creswell 33 and Glaser and Strauss,Reference Glaser and Strauss 34 as we have applied in the past to interview data for studies of brain imaging and health care and parent perspectives on emerging neurotechnologies.Reference Borgelt, Buchman, Weiss and Illes 35

The data were separated from the coded transcripts and reorganized by question to identify patterns and connections among the codes.Reference Miles, Huberman and Saldana 36 Using an interpretive method, the same authors then reintegrated, organized, and reduced the data around central categories and relationships across all transcripts to develop a more refined coding guide. This refined guide was then used to independently code all transcripts, and intercoder differences were reconciled to reach consensus.

Applicable themes and their constituent subthemes were coded only once per transcript per interview question to control for individual biases from participants repeating the same theme multiple times in a long response to an individual question. Each question was coded separately. If a participant returned to a theme in a response to two or more questions, multiple counts would be recorded for that theme.

Results

Framework

Figure 1 depicts the analytic framework. The framework identifies criteria for clinical translation: (1) technical feasibility and quantification of brain imaging data; (2) significant change in outcome; and (3) ethical, social, and legal justifications. Then, the framework provides a decision point to assess clinical actionability. A positive response leads to consideration of the ethical, social, and legal impacts across different groups of stakeholders and institutions. A negative response leads to consideration of challenges and benefits of research.

Figure 1 Analytic framework for discerning clinical actionability of neuroimaging for DoC in Canada. The framework identifies seven test nodes: the patient, family, medical care team, health care system, health research, health policy and law, and scientific knowledge. Each node represents an impact variable of neuroimaging evaluated in the context of actionability within the heterogeneity of TBI, patient autonomy, best practices for health care, and human values.

Interviews

Eleven hours of interview data were collected and analyzed from 22 participants (9 women and 13 men). Participants represented the four target groups as follows: neuroimaging researchers (n=3), practicing physicians (n=8 [3 neurologists, 3 physiatrists, and 2 neurosurgeons]), ethicists (n=6), and law professors (n=5). All participants held advanced degrees: MD, PhD, or JD. Seven of the eight physicians declared that they had more than six years of experience working with patients with DoC. Participants from other disciplines had five years of experience or less working with patients with DoC.

All participants responded affirmatively to whether neuroimaging technology had the potential to be clinically useful in detecting signals of consciousness in vegetative state patients. However, the affirmation of clinical utility was not unconditional, as shown by the analysis of the emergent themes.

Thirteen themes dominated the analysis of 483 units of data from the interviews. Each of these 13 themes was coded at least 10 times. Themes with higher coding instances were assigned a higher rank; the highest-ranked theme was coded 28 times. Table 1 shows the top-ranked themes, organized into two major categories: actionability (n=5) and impact (n=8). The table also shows the fraction of participants who cited each theme at least once during the interviews. Table 2 shows illustrative quotes representing positive views for actionability. Table 3 shows illustrative quotes for skepticism about the utility of neuroimaging to detect signals of consciousness. Table 4 shows illustrative quotes for overall impact.

Table 1 Most frequently coded themes regarding the actionability and impact of neuroimaging technology to detect signals of consciousness in VS patients in Canada

Rankings were determined by the total number of times each theme was referenced in response to a question over all the interviews. Themes shown here each had more than 10 references. The table also shows the percentage of participants who referenced each theme at least once, with separate columns for all participants and for each of the four participant professions.

Table 2 Selected participant perspectives on the actionability of detecting signals of consciousness in VS patients in Canada

Table 3 Examples of skepticism on the clinical utility of neuroimaging to detect signals of consciousness in VS patients in Canada

Table 4 Selected participant perspectives on the impact of detecting signals of consciousness in VS patients in Canada

Responses Concerning Actionability

Validation and calibration of technique

When considering clinical translation of neuroimaging for unresponsive patients, participants most commonly cited challenges around the translation of methods from the bench to the bedside. Practitioners in particular were concerned about the reproducibility and consistency of the signals detected, not only within a single patient but also across patients with different injuries, different hemodynamics, and different medical histories. Other concerns about validation were more complex, with several participants questioning the precise nature of the phenomena being detected.

“If you say the test is determining that there is the presence of consciousness but that’s misleading because you haven’t validated it, then you’re giving them false hope. Or likewise if you’re saying the test cannot detect any sense of consciousness and it’s a hopeless situation but in fact the test missed, wasn’t validated, then you could lead to a change in care that could be a poor outcome for the patient.” (Neurologist PR8)

Uncertain link between signals of consciousness and prognosis

The second highest ranked theme in the category of actionability concerned the correlation of neuroimaging results with patient prognosis, and was cited only by ethicists and practitioners. Participants voiced challenges for neuroimaging in the context of the heterogeneity of consciousness, access to the technique once available for clinical purposes, and the lack of legal guidance to address the problems raised by this technique.

“I would say probably again it goes back to the question about what does the result actually represent? Again, you know, there are still questions even among our clinicians in terms of what they may actually represent in terms of the person’s awareness or the person’s prognosis in the longer term.” (Ethicist ET6)

Criteria for appropriate applications

While reflecting on medical and legal issues involved in the care of patients, participants underscored the need to determine the circumstances under which patients should be referred to neuroimaging, the timing at which such procedures should be administered, and guidelines to guard against overuse and the potential for a drain on the health care economy.

“I think one of the challenges we have…is that in the initial deployment of technology, the appropriate use isn’t always clear. And so I think that there is a risk that we will overuse it, over apply it in the struggle to understand what best practice is. So I think that that does create an economic drain on the health care system.” (Ethicist ET4)

Risks of misinterpretation

In light of the heterogeneity of consciousness, participants described the risks of overinterpreting and underinterpreting signals of consciousness measured by neuroimaging. Underinterpretation was described as wrongly assigning a lower level of consciousness to a patient. Overinterpretation was associated with false hope. In describing these conditions, participants predicted that both would create controversy. The lack of baseline data about residual consciousness in vegetative patients was highlighted, as was the obscurity around the meaning of these signals of consciousness.

“Those issues would have to be considered as its being developed for translation, so it’d be the warning box on the use of the technology…when someone is applying the technology, you would have a disclaimer of its limitation, so that whoever is interpreting the measurement would say, ‘Well this is how we interpret but there’s this margin of error with it,’ type approach.” (Neurologist PR8)

Skepticism about change in outcome

Other concerns related to skepticism about achieving measurable benefit in the patients’ outcome or making a functional change for the patient. In this respect, participants felt that potential changes in signals of consciousness do not necessarily reflect a patient’s clinical status. Although participants valued the use of neuroimaging as an adjunct to the clinical examination, they highlighted the lack of correlation between detecting signals of consciousness and being able to improve the patient’s condition in a meaningful way.

The reasons that participants gave for expressing skepticism about the clinical utility of neuroimaging to detect signals of consciousness extended beyond measures of patient outcome (Table 3). Participants highlighted the difficulties of finding the appropriate clinical window or context to apply neuroimaging in light of the unpredictably evolving nature of DoCs. They felt that the demand to access neuroimaging would be insufficient to warrant further efforts towards clinical translation because, in today’s health care climate at least, families and surrogate decision-makers usually choose to withdraw life-sustaining treatment early. They also expressed concern that the current research findings do not yet make a sufficiently powerful case for clinical translation.

“…you have to prove to me that we can do something with this. We have lots of ways of imaging people’s heads and saying this is what’s wrong with them, but that’s not what I do. What I do is try and make the person so their quality of life is better… We can do a CT of someone’s head and show a big bleed, which is fine…But the bottom line is how can we make the person better?” (Neurologist PR8)

Responses Concerning Impact

Challenges of informed consent

The most frequently reported issue concerning impact was related to challenges of informed consent. Respondents highlighted the difficulties of measuring competence even in patients who are awake (Table 4), let alone from brain-injured individuals using functional brain signals as a proxy for speech.

“… you’re basically giving someone a treatment for which they can’t consent. So, I assume that you’re getting the consent of substitute decision makers because you can’t get consent from someone until you know whether they have any capacity to consent…So, it’s a decision that you’re making for an investigative treatment with the substitute decision maker for that person…I would be wary of getting consent for someone for say another medical procedure through this mechanism until we’re pretty damn sure that it’s really telling us what we think it’s telling us.” (Law Professional LL1)

Burden on health care resources and lack of government support

Participants were concerned that clinical availability of neuroimaging would place greater burdens on health care resources because of an increased demand for access to the technology. In parallel, participants predicted that the Canadian health care system would be unwilling to fund clinical applications for neuroimaging even if future research findings demonstrated evidence of a potential benefit to patients. Their concerns stemmed from the difficulty of obtaining funding from already limited health care resources for other diagnostic tools with well-established benefits.

“The economic concerns are apparent in the sense in which you must take care of the patient.…You will then have a question as to what to do with a patient who you think has not got much hope of ever experiencing a benefit…more and more patients are put in that category, then more and more bed space must be allocated to them, nursing space, and so forth. So that that will be certainly an extra weight that is put on the allocation of resources and the health care dollars.” (Ethicist ET1)

Concerns about public misunderstanding and communicating research

Participants also commented on prerequisites for moving the technique from bench to bedside, including concerns about the expectations and public misunderstanding of neuroimaging, and the need for guidelines specifying appropriate situations in which the technique is indicated. They urged research demonstrating the reliability and reproducibility of neuroimaging to detect signals of consciousness, and suggested translation of peer-reviewed research articles for public communication.

“I think that the scientific community has an obligation to do their best to help the media convey this information in a coherent and accurate and measured way with clear statements about the limitations of our knowledge and the limitations of the potential, as opposed to, now we can connect with everybody who’s in a vegetative state, or whatever the scientific terminology is. I think that the medical community has an obligation to be involved in the dissemination of this information, not just to each other, but to the public as well.” (Law Professional LL1)

Potential to give patients a voice and enhance care

Participants recognized the positive results from assessing residual signs of consciousness in misdiagnosed vegetative patients. These comments touched on the unprecedented ability for patients to voice their preferences, and the accompanying potential of enhancing patient-centered care by taking into account patients’ current wishes. Participants saw the potential for signals of consciousness as an avenue through which patients could exercise their autonomy and attending physicians could understand patient preferences that would otherwise be unstated.

“We’re trying to give them an interface with their environment. We’re trying to get them to be able to communicate their preferences. Do I want to wear a green shirt or a red shirt? Or do I want to watch TV or listen to music? And that kind of autonomy, I think, would be very, very valuable for those kinds of individuals.” (Physiatrist PR2)

Dangers of equating consciousness with competence

Participants felt that demonstration of awareness through neuroimaging is not equivalent to competence. This concern applied specifically to patients’ ability to provide informed consent.

“… You can’t assume there’s competence if there’s consciousness…And likewise on consent, informed consent by definition is you have to be able to repeat what was told to you. So, you could be conscious but if you’re mute you can’t necessarily give informed consent, that’s where you have your advocate.” (Neurologist PR8)

Discussion

We explored expert opinions on the clinical actionability of neuroimaging to detect signals of consciousness in patients diagnosed as vegetative, and identified the impact this technology would have if translated into clinical practice in Canada. All 22 of the participants in this study agreed that the technology has the potential to be clinically actionable, but not without reservation. Overall, participants’ concerns about actionability centered on the need for more translational studies demonstrating reproducible signals, the impact on informed consent, and the challenges around balancing issues of distributive justice and the increasing demands for access to neuroimaging in the face of limited health care resources. They also expressed skepticism about the usefulness of neuroimaging to detect signals of consciousness in DoC patients in the context of the current lack of demonstrable benefits to patients. Participants also recognized a lack of guidance on the appropriate clinical timing and context to prescribe such procedures to patients.

Practitioners (at 36%) represented the largest subgroup of the participant sample. They spoke most frequently about challenges of ensuring validity and reliability for detecting signals of consciousness in behaviourally unresponsive patients. This complements a recent qualitative study with health care professionals providing clinical care to DoC patientsReference Rodrigue, Riopelle, Bernat and Racine 37 that showed difficulty and uncertainty in prognostication. Behavioural evidence of awareness of self or the environment upon clinical examination may suggest residual cognitive function in a subset of minimally conscious patients. Neuroimaging studies have contributed to a better understanding of the neurobiological correlates of residual cognition in MCS patients. Differing patterns of functional connectivityReference Laureys, Owen and Schiff 38 - Reference Cauda, Micon and Sacco 40 and the default mode networkReference Fernández-Espejo, Soddu and Cruse 41 , Reference Vanhaudenhuyse, Noirhomme and Tshibanda 42 have been demonstrated as markers for improving diagnosis and prognosis. Numerous neuroimaging studies of large-scale brain networks in MCS and vegetative state patients have revealed active cortical networks and evidence of language processing, face perception, and sensory functions.Reference Schiff, Ribary and Moreno 43 - Reference Boly, Faymonville and Schnakers 48 However, clinical misdiagnosis between MCS and vegetative state using behavioural criteria continues to be problematic.Reference Andrews, Murphy, Munday and Littlewood 49 , Reference Childs, Mercer and Childs 50 Resolving the conflict between the practitioners’ perceptions and the growing evidence regarding MCS diagnosis and prognosis will be an ongoing challenge to the clinical translation of this technology.

To provide informed consent for medical treatment, a patient must demonstrate decision-making capacity. In considering the impact of clinical translation of neuroimaging research, participants expressed concerns about the circular problem of how behaviourally unresponsive patients could provide informed consent to this procedure. Other commentators have also agreed that providing informed consent is contingent upon the presumption of capacity, which is difficult to assess in DoC patientsReference Appelbaum and Grisso 51 - Reference Appelbaum 53 despite the possibility that they may retain preserved cognition sufficient to meaningfully engage in decision-making.Reference Peterson, Naci and Weijer 54 - Reference Bach and Kerzner 56

Participants were concerned about the effect this technology would have on the cost of health care. However, analysis of the answers to this question is hampered by a lack of reliable PVS and MCS prevalence rates—not just in Canada but worldwide,Reference Pisa, Biasutti, Drigo and Barbone 57 - Reference Fins 59 —and by uncertainty of how detection of signals of consciousness would actually change patient prognosis and treatment and thus affect cost.

Many of the practitioners were cynical about the likelihood of a technology like this being implemented in the Canadian clinical environment, noting that there are advanced imaging and other diagnostic techniques that simply are not funded by the system, even though they have been proven to save money and improve patient outcomes in other countries.

Although many of the participants’ responses were cautionary in nature, there was general consensus that this technology has the potential for improving the quality of care for these vulnerable patients, if only by enabling them to express preferences. This potential and the ethical duty it implies is shared by others.Reference Fins 60

With respect to current research on neuroimaging in patients with DoC, participants were sensible about the need for research ethics guidance for clinical actionability. Participants highlighted the challenges created by public misunderstanding of the limitations of neuroimaging techniques. They reported a range of important practical problems related to the interpretation of neuroimaging findings that could create controversy in the broader clinical community, the patient’s medical care team, and the patient’s family. Given the lack of quality information in the media on brain death, the vegetative and minimally conscious states, and coma,Reference Wijdicks and Wijdicks 61 - Reference Samuel and Kitzinger 64 it is unsurprising that public understanding is often discordant with the views of the medical and scientific communities.Reference Racine and Bell 18 , Reference Wardlaw, O’Connell and Shuler 65 Although participants did identify standard scientific channels (e.g. peer-reviewed journals, scientific conferences) as the chosen method of research dissemination, science communication, unlike the other issues, did not seem to fall directly under the conventional understanding of ethics challenges. Recent studies addressed public understanding of the science of neuroimaging for DoC by recommending an upstream role for an interdisciplinary panel of experts in communicating research findings to the public.Reference Fins, Illes, Bernat, Hirsch, Laureys and Murphy 29 Complexities in science communication highlight the responsibility that scientific, medical, and key public stakeholders share in addressing public communication and understanding.

Limitations

Purposive sampling was restricted to participants from three medical centres within Canada. We recognize the limitations of this selection bias. The numbers of participants in each group were small. Most reported that they did not have technical expertise per se, and they had differing levels of knowledge on DoC or neuroimaging. Theoretical saturation was measured across groups rather than for each group; adequacy of the sample size was established when no new concepts emerged from the review of all interviews conducted.Reference Glaser and Strauss 34 , Reference Morse 66 The study reveals projections of future applications of technology in the Canadian health care setting, not actual experiences. This latter limitation is generally accepted in qualitative research.Reference Kvale 30

Conclusions

This study identified ethical, social, and legal concerns that must be addressed before neuroimaging for signals of consciousness can be a routine part of the clinical care for patients with acquired brain injuries in Canada. It further illuminated the immense knowledge translation task at hand in communicating about advances in modern brain imaging capabilities for DoC.

Acknowledgements

We thank the interview participants for their time and contribution to this study. Support for this research comes from a grant from the Canadian Institutes of Health Research: EOG #120257 and CNE #85117.

Disclosures

GL, ACB, UR, AJS, AT, and CS have nothing to disclose. AMO received research support from Western University Canada Excellence Research Chairs grant, Canadian Institutes of Health Research (CIHR) grant, Canada Foundation for Innovation grant, National Sciences and Engineering Research Council (NSERC) Discovery grant, CIHR Operating grant, McDonnell grant, CIHR Operating grant, and NSERC Research Tools and Instruments grant. JI received support from the Canada Research Chairs Program and CIHR grants EOG #120257 and CNE #85117. JI and AMO both hold grant support on the topic of neuroimaging and disorders of consciousness from the CIHR.

References

1. Chen, A, Bushmeneva, K, Zagorski, B, Colantonio, A, Parsons, D, Wodchis, WP. Direct cost associated with acquired brain injury in Ontario. BMC Neurol. 2012;12:76. Available from: http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3518141&tool=pmcentrez&rendertype=abstract.CrossRefGoogle ScholarPubMed
2. Colantonio, A, Croxford, R, Farooq, S, Laporte, A, Coyte, PC. Trends in hospitalization associated with traumatic brain injury in a publicly insured population, 1992-2002. J Trauma. 2009;66:179-183.Google Scholar
3. Langlois, JA, Rutland-Brown, W, Wald, MM. The epidemiology and impact of traumatic brain injury: abrief overview. J Head Trauma Rehabil. 2006;21:375-378.Google Scholar
4. Owen, A, Coleman, M, Boly, M, Davis, M, Laureys, S, Pickard, JD. Detecting awareness in the vegetative state. Science. 2006;313:1402. Available from: http://www.sciencemag.org/content/313/5792/1402.short.Google Scholar
5. Monti, MM, Vanhaudenhuyse, A, Coleman, MR, et al. Willful modulation of brain activity in disorders of consciousness. N Engl J Med. 2010;362:579-589.Google Scholar
6. Medical aspects of the persistent vegetative state (2). The Multi-Society Task Force on PVS. N Engl J Med. 1994;330(22):1572-1579.Google Scholar
7. Moreno, RD, Schiff, N, Giacino, J, Kalmar, K, Hirsch, J. A network approach to assessing cognition in disorders of consciousness. Neurology. 2011;75:1871-1878.Google Scholar
8. Fernández-Espejo, D, Owen, AM. Detecting awareness after severe brain injury. Nat Rev Neurosci. 2013;14:801-809.CrossRefGoogle ScholarPubMed
9. Monti, MM, Coleman, MR, Owen, AM. Neuroimaging and the vegetative state: Resolving the behavioral assessment dilemma? Ann N Y Acad Sci. 2009;1157:81-89.CrossRefGoogle ScholarPubMed
10. Lunau, K. Inside a comatose mind. Macleans. 2013. Available from: http://www.macleans.ca/society/technology/beyond-words/.Google Scholar
11. Wilkinson, D, Kahane, G, Savulescu, J. “Neglected personhood” and neglected questions: remarks on the moral significance of consciousness. Am J Bioeth. 2010;8:31-33.Google Scholar
12. Fins, JJ. Border zones of consciousness: another immigration debate? Am J Bioeth. 2007;7:51-54; discussion W1-4.Google Scholar
13. Ribary, U. Dynamics of thalamo-cortical network oscillations and human perception. Prog Brain Res. 2005;150:127-142.Google Scholar
14. Ribary, U, Doesburg, S, Ward, L. Thalamocortical network dynamics: a framework for typical/atypical cortical oscillations and connectivity. In: Supek S, Aine AJ, editors. Magnetoencephalography – from signals to dynamic cortical networks. Heidelberg: Springer Verlag; 2014, p. 429-450.Google Scholar
15. Monti, MM, Coleman, MR, Owen, AM. Executive functions in the absence of behavior: functional imaging of the minimally conscious state. Prog Brain Res. 2009;177:249-260.CrossRefGoogle ScholarPubMed
16. Coleman, MR, Bekinschtein, T, Monti, MM, Owen, A, Pickard, JD. A multimodal approach to the assessment of patients with disorders of consciousness. Progr Brain Res. 2009;177:231-248.Google Scholar
17. Illes, J, De Vries, R, Cho, MK, Schraedley-Desmond, P. ELSI priorities for brain imaging. Am J Bioeth. 2006;6:W24-W31.Google Scholar
18. Racine, E, Bell, E. Clinical and public translation of neuroimaging research in disorders of consciousness challenges current diagnostic and public understanding paradigms. Am J Bioeth. 2008;8:13-15.Google Scholar
19. Wilkinson, DJ, Kahane, G, Horne, M, Savulescu, J. Functional neuroimaging and withdrawal of life-sustaining treatment from vegetative patients. J Med Ethics. 2009;35:508-511.CrossRefGoogle ScholarPubMed
20. Kahane, G, Savulescu, J. Brain damage and the moral significance of consciousness. J Med Philos. 2009;34:6-26.Google Scholar
21. Fins, J. Neuroethics, neuroimaging, and disorders of consciousness: promise or peril? Trans Am Clin Climatol Assoc. 2010;122:336-346.Google Scholar
22. Lanoix, M. Where angels fear to tread: proxy consent and novel technologies. Brain Inj. 2010;24:1336-1342.Google Scholar
23. Tovino, S, Winslade, W. A primer on the law and ethics of treatment, research, and public policy in the context of severe traumatic brain injury. Ann Heal Law. 2005;14:1-52.Google Scholar
24. Cooper, AB, Chidwick, P, Sibbald, R. Court rules that withdrawal of life support is a plan of treatment requiring consent. Can Med Assoc J. 2011;183:E467.Google Scholar
25. Dyer, O. Doctors fail to get life support withdrawn from “minimally conscious” patient. BMJ Br Med J. 2013;347:f6366.CrossRefGoogle ScholarPubMed
26. Lee, G, Illes, J. Never say never: limitations of neuroimaging for communicating decisions after brain injury. AJOB Neurosci. 2013;4:3-4.Google Scholar
27. Jox, RJ, Bernat, JL, Laureys, S, Racine, E. Disorders of consciousness: responding to requests for novel diagnostic and therapeutic interventions. Lancet Neurol. 2012;11:732-738.Google Scholar
28. Koehler, PJ, Wijdicks, EFM. Historical study of coma: looking back through medical and neurological texts. Brain. 2008;131:877-889.Google Scholar
29. Fins, JJ, Illes, J, Bernat, JL, Hirsch, J, Laureys, S, Murphy, E. Neuroimaging and disorders of consciousness: envisioning an ethical research agenda. Am J Bioeth Ajob. 2008;8:3-12.CrossRefGoogle ScholarPubMed
30. Kvale, S. Dominance through interviews and dialogues. Qual Inq. 2006;12:480-500.Google Scholar
31. Boeije, H. A purposeful approach to the constant comparative method in the analysis of qualitative interviews. Qual Quant. 2002;36:391-409.Google Scholar
32. Creswell, J. Qualitative inquiry and research design. 3rd ed. Thousand Oaks, CA: SAGE Publications; 2013. p. 472.Google Scholar
33. Creswell, JW. Research design: qualitative, quantitative, and mixed methods approaches. 2nd ed. Thousand Oaks, CA: SAGE Publications; 2003.Google Scholar
34. Glaser, B, Strauss, A. The discovery of grounded theory: strategies for qualitative research. Chicago: Aldine; 1967.Google Scholar
35. Borgelt, EL, Buchman, DZ, Weiss, M, Illes, J. In search of “anything that would help”: parent perspectives on emerging neurotechnologies. J Atten Disord. 2012;18:395-401.Google Scholar
36. Miles, MB, Huberman, AM, Saldana, J. Qualitative data analysis: a methods sourcebook. 2nd ed. Thousand Oaks, CA: SAGE Publications; 1994.Google Scholar
37. Rodrigue, C, Riopelle, RJ, Bernat, JL, Racine, E. Perspectives and experience of healthcare professionals on diagnosis, prognosis, and end-of-life decision making in patients with disorders of consciousness. Neuroethics. 2013;6:25-36.Google Scholar
38. Laureys, S, Owen, A, Schiff, N. Brain function in coma, vegetative state, and related disorders. Lancet Neurol. 2004;3:537-546.Google Scholar
39. Boly, M, Massimini, M, Tononi, G. Theoretical approaches to the diagnosis of altered states of consciousness. Prog Brain Res. 2009;177:383-398.CrossRefGoogle Scholar
40. Cauda, F, Micon, BM, Sacco, K, et al. Disrupted intrinsic functional connectivity in the vegetative state. J Neurol Neurosurg Psychiatry. 2009;80(4):429-431.Google Scholar
41. Fernández-Espejo, D, Soddu, A, Cruse, D, et al. A role for the default mode network in the bases of disorders of consciousness. Ann Neurol. 2012;72:335-343.Google Scholar
42. Vanhaudenhuyse, A, Noirhomme, Q, Tshibanda, LJ-F, et al. Default network connectivity reflects the level of consciousness in non-communicative brain-damaged patients. Brain. 2010;133:161-171.Google Scholar
43. Schiff, ND, Ribary, U, Moreno, DR, et al. Residual cerebral activity and behavioural fragments can remain in the persistently vegetative brain. Brain. 2002;125(Pt 6):1210-1234.CrossRefGoogle ScholarPubMed
44. Laureys, S, Faymonville, ME, Peigneux, P, et al. Cortical processing of noxious somatosensory stimuli in the persistent vegetative state. Neuroimage. 2002;17:732-741.Google Scholar
45. Boly, M, Faymonville, M-E, Peigneux, P, et al. Auditory processing in severely brain injured patients. Arch Neurol. 2004;61:233-238.Google Scholar
46. Laureys, S, Perrin, F, Faymonville, M, et al. Cerebral processing in the minimally conscious state. Neurology. 2004;63:916-918.CrossRefGoogle ScholarPubMed
47. Coleman, MR, Rodd, JM, Davis, MH, et al. Do vegetative patients retain aspects of language comprehension? Evidence from fMRI. Brain. 2007;130:2494-2507.Google Scholar
48. Boly, M, Faymonville, ME, Schnakers, C, et al. Perception of pain in the minimally conscious state with PET activation: an observational study. Lancet Neurol. 2008;7:1013-1020.Google Scholar
49. Andrews, K, Murphy, L, Munday, R, Littlewood, C. Misdiagnosis of the vegetative state: retrospective study in a rehabilitation unit. BMJ. 1996;313:13-16.Google Scholar
50. Childs, N, Mercer, W, Childs, H. Accuracy of diagnosis of persistent vegetative state. Neurology. 1993;43:1465-1467.Google Scholar
51. Appelbaum, P, Grisso, T. The MacArthur Treatment Competence Study. I: mental illness and competence to consent to treatment. Law Hum Behav. 1995;19:105-126.Google Scholar
52. Karlawish, J. Measuring decision-making capacity in cognitively impaired individuals. NeuroSignals. 2008;16:91-98.Google Scholar
53. Appelbaum, PS. Consent in impaired populations. Curr Neurol Neurosci Rep. 2010;10:367-373.CrossRefGoogle ScholarPubMed
54. Peterson, A, Naci, L, Weijer, C, et al. Assessing decision making capacity in the behaviorally non-responsive patient with residual covert awareness. AJOB Neurosci. 2013;4:3-14.Google Scholar
55. Peterson, A, Naci, L, Weijer, C, Owen, AM. A principled argument, but not a practical one. AJOB Neurosci. 2013;4:52-53.Google Scholar
56. Bach, M, Kerzner, L. A new paradigm for protecting autonomy and the right to legal capacity. Prepared for the Law Commission of Ontario. 2010. Available from: http://www.lco-cdo.org/disabilities/bach-kerzner.pdf.Google Scholar
57. Pisa, FE, Biasutti, E, Drigo, D, Barbone, F. The prevalence of vegetative and minimally conscious states: a systematic review and methodological appraisal. J Head Trauma Rehabil. 2014;29:E23-E30.Google Scholar
58. Craemer, R. Funding arrangements for diagnostic imaging services: an international literature review. Prepared for the Department of Health and Ageing. 2010. Available from: http://www.thescannermagazine.com/images/pdfs/pdf16.pdf.Google Scholar
59. Fins, J. Brain injury: the vegetative and minimally conscious states. In: Crowley M, editor. From Birth to Death Bench to Clinic. The Hastings Center. Bioethics Briefing Book for Journalists, Policymakers, and Campaigns. Garrison, NY: The Hastings Center; 2008. p. 15-20; Available from: http://childpsychaitry.thehastingscenter.org/uploadedFiles/Publications/Briefing_Book/braininjurychapter.pdf.Google Scholar
60. Fins, J. Constructing an ethical stereotaxy for severe brain injury: balancing risks, benefits and access. Nat Rev Neurosci. 2003;4:3-7.Google Scholar
61. Wijdicks, EFM, Wijdicks, MF. Coverage of coma in headlines of US newspapers from 2001 through 2005. Mayo Clin Proc. 2006;81:1332-1336.Google Scholar
62. Racine, E, Bar-Ilan, O, Illes, J. fMRI in the public eye. Nat Rev Neurosci. 2005;6:159-164.Google Scholar
63. Racine, E, Bar-Ilan, O, Illes, J. Brain imaging: a decade of coverage in the print media. Sci Commun. 2006;28:122-142.Google Scholar
64. Samuel, G, Kitzinger, J. Reporting consciousness in coma: media framing of neuro-scientific research, hope, and the response of families with relatives in vegetative and minimally conscious states. JOMEC J. 2013;3:1-15.Google Scholar
65. Wardlaw, JM, O’Connell, G, Shuler, K, et al. “Can it read my mind?” - What do the public and experts think of the current (mis)uses of neuroimaging? PLoS One. 2011;6:e25829.CrossRefGoogle ScholarPubMed
66. Morse, JM. The significance of saturation. Qual Health Res. 1995;5:147-149.Google Scholar
Figure 0

Figure 1 Analytic framework for discerning clinical actionability of neuroimaging for DoC in Canada. The framework identifies seven test nodes: the patient, family, medical care team, health care system, health research, health policy and law, and scientific knowledge. Each node represents an impact variable of neuroimaging evaluated in the context of actionability within the heterogeneity of TBI, patient autonomy, best practices for health care, and human values.

Figure 1

Table 1 Most frequently coded themes regarding the actionability and impact of neuroimaging technology to detect signals of consciousness in VS patients in Canada

Figure 2

Table 2 Selected participant perspectives on the actionability of detecting signals of consciousness in VS patients in Canada

Figure 3

Table 3 Examples of skepticism on the clinical utility of neuroimaging to detect signals of consciousness in VS patients in Canada

Figure 4

Table 4 Selected participant perspectives on the impact of detecting signals of consciousness in VS patients in Canada