Rehabilitation technologies and interventions for individuals with spinal cord injury: translational potential of current trends (2024)

Abstract

In the past, neurorehabilitation for individuals with neurological damage, such as spinal cord injury (SCI), was focused on learning compensatory movements to regain function. Presently, the focus of neurorehabilitation has shifted to functional neurorecovery, or the restoration of function through repetitive movement training of the affected limbs. Technologies, such as robotic devices and electrical stimulation, are being developed to facilitate repetitive motor training; however, their implementation into mainstream clinical practice has not been realized. In this commentary, we examined how current SCI rehabilitation research aligns with the potential for clinical implementation. We completed an environmental scan of studies in progress that investigate a physical intervention promoting functional neurorecovery. We identified emerging interventions among the SCI population, and evaluated the strengths and gaps of the current direction of SCI rehabilitation research. Seventy-three study postings were retrieved through website and database searching. Study objectives, outcome measures, participant characteristics and the mode(s) of intervention being studied were extracted from the postings. The FAME (Feasibility, Appropriateness, Meaningfulness, Effectiveness, Economic Evidence) Framework was used to evaluate the strengths and gaps of the research with respect to likelihood of clinical implementation. Strengths included aspects of Feasibility, as the research was practical, aspects of Appropriateness as the research aligned with current scientific literature on motor learning, and Effectiveness, as all trials aimed to evaluate the effect of an intervention on a clinical outcome. Aspects of Feasibility were also identified as a gap; with two thirds of the studies examining emerging technologies, the likelihood of successful clinical implementation was questionable. As the interventions being studied may not align with the preferences of clinicians and priorities of patients, the Appropriateness of these interventions for the current health care environment was questioned. Meaningfulness and Economic Evidence were also identified as gaps since few studies included measures reflecting the perceptions of the participants or economic factors, respectively. The identified gaps will likely impede the clinical uptake of many of the interventions currently being studied. Future research may lessen these gaps through a staged approach to the consideration of the FAME elements as novel interventions and technologies are developed, evaluated and implemented.

Electronic supplementary material

The online version of this article (10.1186/s12984-018-0386-7) contains supplementary material, which is available to authorized users.

Keywords: Spinal cord injury, Rehabilitation, Technology, Clinical implementation, Environmental scan

Background

The past three decades have seen a shift in the focus of neurorehabilitation from the use of compensatory approaches to enable function toward an emphasis on functional neurorecovery, or promoting the restoration of function through use of the affected limbs. The shift from compensation to neurorecovery has been most apparent in the rehabilitation of individuals with incomplete spinal cord injury (SCI) [1]. For example, 30years ago the rehabilitation of walking for those with incomplete SCI consisted of learning to use assistive devices. As basic research concerning the spinal control of locomotion was translated to humans, the potential for these individuals to recover independent walking ability was revealed. Through repetitive exposure to weight-supported stepping on a treadmill, spinal cats regained some walking function [2]. These discoveries, and their subsequent translation to humans with incomplete SCI [3], resulted in a paradigm shift from compensation to neurorecovery.

Our understanding of the potential for neuroplasticity following a SCI has contributed to the development of intensive physical interventions that aim to promote neurorecovery through repetitive movement training [4]. To facilitate the intensive training process, therapeutic technologies have been developed, such as exoskeletons, functional electrical stimulation (FES), and robotic rehabilitation devices. While clinicians have an interest in incorporating technology that may augment neurorecovery into practice, the actual uptake of technology in neurorehabilitation has been low [57].

As consumers and providers of rehabilitative interventions, clinicians must consider client preferences, scientific evidence, previous clinical experience and available resources (e.g. equipment, time, staffing) when choosing an intervention. The FAME (Feasibility, Appropriateness, Meaningfulness, Effectiveness and Economic Evidence) framework was developed to assist clinicians with the implementation of evidence-based practices [8, 9]. The framework outlines five elements to consider when deciding whether or not to implement an intervention or technology.

  1. Feasibility: whether the intervention is practical (i.e. concerned with the actual doing of something rather than theory) and practicable (i.e. the ability to successfully implement into practice) given the cultural, physical and financial context.

  2. Appropriateness: whether the intervention fits within a therapeutic scenario and the current health care context.

  3. Meaningfulness: whether the intervention and outcomes matter to the target population, setting and culture. Meaningfulness relates to the personal experience, perceptions, values, thoughts, and beliefs of each individual patient.

  4. Effectiveness: whether the intervention achieves the intended effect, which may be a clinical or health service outcome.

  5. Economic Evidence: whether the cost-to-benefit ratio supports implementation of the intervention.

While the intended users of the FAME framework are clinicians, knowledge translation and implementation are processes shared amongst the research and clinical communities. Ideally researchers also consider the FAME elements when designing novel interventions and research studies for neurorehabilitation. Interventions and technologies satisfying the FAME elements may be adopted more readily by clinicians and hence, make more tangible impacts on patient outcomes and the neurorehabilitation field.

Given the shift in the focus of SCI rehabilitation from compensation to neurorecovery, and the development of technology to support this direction, we wished to consider how SCI rehabilitation research aligns with the potential for clinical implementation. To do this we completed an environmental scan of current SCI rehabilitation research to: 1) Identify emerging physical interventions that aim to promote neurorecovery among the SCI population, and 2) Evaluate the strengths and gaps of the current direction of SCI rehabilitation research using the FAME framework as a guide for evaluation.

Methods

An environmental scan of clinical trials for the SCI population was completed from June 8–July 5 2017. Environmental scans are often performed to examine a field as a whole in order to provide evidence of its current direction, to raise awareness of issues or gaps, and to plan future initiatives and strategies [10].

Search strategies

Sources of information included databases or websites that list ongoing research studies for SCI. Due to the time lag between the conduct and publication of research studies, we examined research currently being conducted and not yet published. Nine websites listing SCI research studies were accessed: ClinicalTrials.gov, Craig H. Neilsen Foundation, Spinal Cord Outcomes Partnership Endeavor, International Collaboration On Repair Discoveries, Wings for Life, Unite 2 Fight Paralysis, and Rick Hansen Institute, whose website also directed us to the websites for Spinal Cord Injury Ontario and Spinal Cord Injury Alberta. The research studies listed on these websites were reviewed by two authors (MS, KEM) to identify studies adhering to the following inclusion/exclusion criteria:

Inclusion criteria:

  • Participants included individuals with SCI (traumatic or non-traumatic cause) aged ≥16years at any time since injury (i.e. < 1year post-injury or acute/sub-acute, and ≥ 1year post-injury or chronic).

  • The primary intervention(s) being studied was a physical intervention (not a surgical, pharmacological or cell-based intervention) that aimed to promote neurorecovery.

  • Study status was either active but not yet recruiting, recruiting, enrolling, or data collection complete but not yet published.

Exclusion criteria:

  • Studies with an unknown status that had not been updated in > 2years, or for which published results were found.

  • Insufficient study information (> 50% of study details were missing, see Data Extraction below).

  • Cross-sectional studies (i.e. studies involving a single exposure to a physical intervention as this was unlikely to induce neurorecovery).

All study postings were reviewed on each website, with the exception of Clinicaltrials.gov where a search was performed. The search criteria used reflected the above inclusion and exclusion criteria.

Data extraction and synthesis

Information about each included study was extracted from the website and compiled into a data extraction table by one author (MS). Information gathered included: source of study posting, study status, location of study, study objectives, outcome measures, and injury characteristics of the targeted participants, such as neurological levels of injury and time since injury. We also documented whether the study included an evaluation of the economic feasibility, participants’ perspectives (e.g. qualitative interviews) and an assessment of the clinical utility (i.e. ease of use in a clinical environment) of the intervention(s) being examined.

Each study was classified by the type or mode of physical intervention used. Due to our focus on interventions that promote neurorecovery, we anticipated that the majority of interventions would be activity-based therapies (ABT). With ABT neuroplasticity is driven by repetitive neuromuscular activation below the level of spinal injury, typically achieved through intensive, task-specific movement practice. Some modes were anticipated in advance and identified a priori; for example, robotics, virtual reality, electrical stimulation, and repetitive movement training without emerging technology (e.g. treadmill or overground gait training). Interventions using electrical stimulation were further divided into three groups according to the site of stimulation: brain, spinal cord or peripheral nervous system (i.e. FES). The target function of the intervention was also noted (i.e. upper extremity function, lower extremity function, and/or trunk function).

Evaluation of strengths and gaps

The strengths and gaps of current SCI rehabilitation research were identified through consideration of the five FAME elements and the environmental scan results. Feasibility was divided into separate evaluations of whether the studied intervention was practical and practicable, and Appropriateness was divided into four sub-elements: institution, clinician, patient and scientific evidence. The authors determined, through consensus, whether each element or sub-element reflected a strength or a gap. Answering ‘yes’ to the following guiding questions suggested that the element was a strength.

  1. Feasibility: Practical: Does the study involve application of an intervention to a target population? Practicable: Does the study involve an intervention that is clinically feasible? For example, an intervention requiring specialized equipment and/or knowledge or training would be considered less clinically feasible. Is a measure of clinical utility included in the study?

  2. Appropriateness: Institution: Do hospitals/rehabilitation centers commonly have the resources (e.g. space, manpower, finances) required to administer the intervention? Clinician: Is the intervention likely to meet the needs of clinicians? For example, does it reflect real-world tasks, measure performance, and encourage variability in movement patterns while simultaneously preventing practice of compensatory movement strategies [6]? Patient: Is the intervention likely to meet the needs of individuals with SCI participating in rehabilitation, given their priorities [11] and stage of recovery? Scientific Evidence: Does the intervention align with principles of motor learning and neuroplasticity [12]? For example, does the intervention involve motor practice that is task-specific and intensive (i.e. many repetitions), and elicits voluntary participation from the patient?

  3. Meaningfulness: Does the study include documentation of the participants’ perspectives on the intervention and/or its intended outcome? Meaningfulness may be assessed through qualitative methods, such as semi-structured interviews or focus groups, or through goal attainment scaling. Structured questionnaires may also probe meaningfulness, albeit without the depth of understanding provided by qualitative methodologies.

  4. Effectiveness: Does the study include evaluation of the effect of the intervention?

  5. Economic Evidence: Does the study include evaluation of economic factors?

Results

Environmental scan results

A total of 1614 study postings were found. After de-duplicating and screening for inclusion, 73 studies were included. Sixty-nine of the 73 studies were returned in the ClinicalTrials.gov database. This database involves a review process that provides standardization for study description; hence, the quality of study postings was high for the majority of included postings. Most studies (n = 49, 67%) were actively recruiting participants (Table1). The majority of research studies were being conducted in North America (n = 54, 74%) or Europe (n = 15, 21%). Two studies were being completed in Thailand, one in Israel and one in China. The bias of inclusion toward the western world likely reflects the sources of information accessed for the environmental scan.

Table 1.

Study and participant characteristics

Number of studies (% of sample (n = 73))
Study status
 Not yet recruiting7 (10%)
 Actively recruiting49 (67%)
 Ongoing study, no longer recruiting10 (14%)
 Data collection complete3 (4%)
 Not specifieda4 (5%)
Participant Characteristics
 Injury Severity:
  Incomplete33 (45%)
  Complete3 (4%)
  Incomplete & complete9 (12%)
  Not specified28 (39%)
 Time Since Injuryb
  Chronic27 (37%)
  Sub-acute7 (10%)
  Chronic & sub-acute28 (38%)
  Not specified11 (15%)

Open in a new tab

aStudy status not reported, but published study results were not found

bChronic = ≥ 1year post-injury; sub-acute = < 1year post-injury

Given our focus on neurorecovery, it was not surprising that the sub-group of SCI most commonly targeted was individuals with incomplete SCI (n = 33, 45%) (Table 1). Participants with chronic injuries (37%, n = 27) were more commonly targeted than those with sub-acute SCI (n = 7, 10%).

Electrical stimulation was the mode of intervention being studied in 20 studies (27%) (Table2). Various applications of brain stimulation were being investigated, as was epidural stimulation of the spinal cord, and surface or implanted FES systems for the upper or lower limbs and/or trunk. Sixteen studies (22%) were examining repetitive movement training without the use of emerging technology, such as overground gait training, balance exercises, upper limb exercises and dance/yoga, to name a few (Table 2). ABT with robotic devices were being investigated in 15 studies (21%); with the majority employing lower extremity exoskeletons or the Lokomat®. Six study postings described research on the effects of intermittent hypoxia on voluntary movement and function, primarily of the lower extremity. Five research studies were incorporating a form of virtual reality into the ABT. Nine studies (12%) employed a combination of two forms of electrical stimulation, such as brain stimulation paired with peripheral nerve stimulation (i.e. paired associative stimulation), or a combination of stimulation with movement practice using a robotic device.

Table 2.

Intervention characteristics

Number of studies (% of total (n = 73))
Mode
 Electrical stimulation20 (27%)
 Brain8 (11%)
  tDCS2 (3%)
  rTMS4 (5%)
  DBS2 (3%)
 Spinal Cord4 (5%)
  Epidural4 (5%)
 PNS (i.e. FES)8 (11%)
  Surface FES for UE4 (5%)
  Surface FES for UE and LE (cycling)1 (1%)
  Implanted FES for LE2 (3%)
  Implanted FES for trunk1 (1%)
 Repetitive Movement Traininga16 (22%)
  Overground gait training5 (7%)
  “Locomotor training”b2 (3%)
  BWSTT1 (1%)
  TT in aquatic environment1 (1%)
  Cycling1 (1%)
  Dance/yoga1 (1%)
  Balance exercises1 (1%)
  Weight-bearing exercisesc2 (3%)
  UE exercises2 (3%)
 Robotics15 (21%)
  LE exoskeleton9 (12%)
  Lokomat3 (4%)
  UE robotic device (1 brain-controlled)2 (3%)
  LE & UE robotic device1 (1%)
 Combination9 (12%)
  Two types of stimulation (i.e. brain + SC or FES)6 (8%)
  Robotics + stimulation (i.e. brain or SCI)3 (4%)
 Intermittent Hypoxia6 (8%)
  LE function5 (7%)
  UE function1 (1%)
 Virtual Reality5 (7%)
  Walking/LE function3 (4%)
  UE function & trunk (virtual sailing)1 (1%)
  Not specified1 (1%)
 Whole-body vibration (LE)1 (1%)
 Low-level laser therapyd1 (1%)
Target Function
 LE46 (63%)
 UE15 (22%)
 Trunk (seated balance)1 (1%)
 LE & UE10 (13%)
 UE & trunk1 (1%)

Open in a new tab

aWithout technology or therapeutic assistive devices

bDetails of locomotor training not specified

cSit-to-stand exercises in one study

dAim is to affect sensory and motor function. tDCS = transcranial direct current stimulation; rTMS = repetitive transcranial magnetic stimulation; DBS = deep brain stimulation; PNS = peripheral nerve stimulation; FES = functional electrical stimulation; LE = lower extremity; UE = upper extremity; BWSTT = body weight-supported treadmill training; TT = treadmill training; SC = spinal cord; SCI = spinal cord injury

Strengths and gaps

The FAME elements of feasibility (practical), appropriateness (scientific evidence), and effectiveness were identified as strengths of current SCI rehabilitation research, while the remaining FAME elements were deemed to be gaps (see Table3).

  1. Feasibility: Current SCI rehabilitation research is practical; it is concerned with the application of interventions. The interventions being researched are less practicable. Two thirds of the research involved electrical stimulation, robotics, virtual reality, or a combination of these technologies, all of which require specialized equipment and knowledge. Ten research postings (14%) listed a measure of clinical utility among the study outcomes.

  2. Appropriateness: Institution: Financial, staffing and space constraints likely limit the appropriateness of the interventions currently being studied. The expertise required to operate and to repair emerging technology, such as robotic devices and brain stimulation, is typically not found amongst the neurorehabilitation team.

Table 3.

Strengths and gaps

FAME Element
Feasibility
 Practical+
 Practicable
Appropriateness
 Institution
 Clinician
 Patient
 Scientific Evidence+
Meaningfulness
Effectiveness+
Economic Evidence

Open in a new tab

+ indicates a strength; indicates a gap

Clinician: Although many of the interventions attempt to mimic real-world tasks, such as overground walking, the extent to which the interventions emphasize the quality of movement (i.e. minimization of compensatory movement strategies) is not clear.

Patient: Lower extremity function, including walking, was most commonly targeted by the studies (n = 46, 63%). However, regaining arm and hand function is the top priority for individuals with incomplete tetraplegia [11], who represent 45% of the SCI population [13]. In addition, little research (n = 2, 3%) was focused on improving trunk function, which is a prerequisite for effective movement of the upper limb. Furthermore, SCI rehabilitation research is focused on chronic SCI, most likely to eliminate the effects of natural recovery. Inclusion of participants with sub-acute SCI would be more appropriate for the therapeutic context (i.e. inpatient and outpatient rehabilitation), and aligns with the window of opportunity for neuroplasticity [4, 12].

Scientific Evidence: Many of the interventions being studied were designed with the principles of motor learning and neuroplasticity in mind. The majority of interventions involved repetitive, task-specific movement training. The exceptions were studies (n = 8, 10%) evaluating the effects of intermittent hypoxia, whole body vibration and low-level laser.

  • 3)

    Meaningfulness: Only five studies (7%) documented the participants’ perspectives on the effects of an intervention (i.e. Canadian Occupational Performance Measure (n = 3) or a semi-structured interview (n = 2)). An additional six (8%) included a questionnaire about participants’ opinions on the device or intervention being tested. About one third of studies included a measure of quality of life; however, quality of life and meaningfulness may not equate.

  • 4)

    Effectiveness: The majority of studies included measures of body structure and function or activity according to the International Classification of Functioning, Disability and Health (ICF) [14]. Measures of gait (n = 41, 56%), balance/postural control (n = 25, 34%), upper extremity function (n = 19, 26%), independence (n = 19, 26%), strength (n = 17, 23%), and sensorimotor function (e.g. the International Standards for Neurological Classification of SCI (ISNCSCI) exam, motor evoked potentials) (n = 11, 15%) were included.

  • 5)

    Economic Evidence: Only two of the 73 studies (3%) mentioned evaluating one or more economic factors. One study planned to document the number of staff required during two modes of locomotor training, as well as other economic factors that were not specified in the posting. The second study planned to evaluate whether locomotor training affects the use of a personal care attendant and/or in-home nursing care.

Discussion

We completed an environmental scan to identify 73 active studies researching physical interventions that promote neurorecovery among adults with SCI. Emerging interventions included repetitive movement practice supplemented with technology, such as robotic devices, virtual reality and electrical stimulation of the central or peripheral nervous systems. What is the likelihood that these interventions can be successfully implemented into clinical practice? The clinical uptake of these technologies into SCI rehabilitation has received little study to-date; however, previous work in stroke rehabilitation would suggest the likelihood is not high. FES, robotics and Wii or Kinect systems are infrequently used by clinicians working with individuals who have experienced a stroke [57]. Numerous barriers to the clinical implementation of rehabilitative technology exist. For example, a lack of knowledge about the technology combined with little or no allocated time to learn [6, 7]. The technology may be perceived too time-consuming to set-up and/or administer, detracting from a patient’s allocated therapy time [6, 7]. Technologies may be perceived to disrupt clinician-patient interactions [6]; for example, physical therapists prefer to use their hands to facilitate movement rather than FES [7]. There are financial barriers as well. The cost and maintenance of some technologies may exceed what a clinical environment can afford. Identifying and addressing barriers early in the development and study of interventions is crucial for the research to clinical translation [15].

The Effectiveness element of the FAME framework was considered a strength of current SCI rehabilitation research. The evaluation of the effects of an intervention can occur under controlled conditions, such as in a laboratory setting; referred to as an efficacy trial [16]. Alternatively an intervention may be studied under ‘real-world’ conditions, as would be the case if the study setting was a hospital and/or with a heterogeneous group of patients; this is an effectiveness trial [16]. While the FAME Framework does not distinguish between efficacy and effectiveness, we believe it is important to acknowledge that these two types of trials address different research questions, with efficacy trials evaluating whether an intervention works and how large the effect is, and effectiveness trials evaluating whether the intervention’s efficacy persists in clinical practice [16]. We suspect that the majority of studies included in the environmental scan were efficacy trials. Moving forward, the study of SCI rehabilitation interventions should include efficacy trials followed by evaluations of effectiveness if efficacy was achieved, as this process is likely to facilitate the identification of barriers and implementation in clinical environments.

From the environmental scan it seemed that few studies planned to evaluate relevant economic factors; however, it is possible that a separate economic analysis was planned, but not reported. Further, the two studies that included an economic aspect specified resource utilization (i.e. staffing) as the focus. It may be that more detailed and lengthy economic analyses, such as the number of quality-adjusted-life-years (QALY) afforded by an intervention [15], are not considered until the effectiveness of an intervention is established. It has also been suggested that unfavorable findings from economic analyses can stall the research of novel technologies that only benefit a small group of people, such as those with SCI [15]. Hence, there may be justification to perform economic analyses at a later stage in the research process.

In sum, there are gaps in current SCI rehabilitation research that will likely impede the clinical implementation of many of the interventions under investigation. Future research should aim to lessen these gaps through consideration of the FAME Framework during the development, evaluation and implementation of novel rehabilitation interventions or technologies. We suggest a staged approach to the consideration of FAME elements (Fig.1). For example, in the early stage of uncontrolled trials, researchers may consider the Feasibility (practicality) and begin an evaluation of Appropriateness by considering the face validity of the intervention. This may involve scanning relevant literature and eliciting input from end-users. Incorporating feedback from clinicians into the design of interventions, or adopting user-centered designs, may lessen the gap between the interventions being studied and the therapeutic context [15]. Following this early stage, controlled or efficacy trials are encouraged to collect data concerning Meaningfulness, efficacy (Effectiveness) and Economic factors (i.e. costs and resource utilization), in addition to the ongoing consideration of practicality (Feasibility) and Appropriateness. It would also be an appropriate time to consider the clinical utility of the intervention and anticipate the barriers to its implementation – i.e., how practicable the intervention is (Feasibility). Finally, the Effectiveness of the intervention may be evaluated, as well as consideration of the Appropriateness of the intervention at the level of the health care institution. An Economic analysis that considers cost:benefit or QALY may also be completed. By considering the FAME Framework throughout the research process, the successful translation of novel interventions or technologies from research to clinical practice may be realized.

Fig. 1.

Rehabilitation technologies and interventions for individuals with spinal cord injury: translational potential of current trends (1)

Open in a new tab

While the FAME elements provide a framework to comprehensively evaluate the translational potential of new rehabilitation interventions, it is important to consider the elements of the model together rather than in isolation. For example, if an intervention is found to be highly effective, a consensus may be reached that some modifications to clinical processes are warranted in order to incorporate the new technique. These modifications might in turn entail a reevaluation of feasibility considerations.

Conclusion

In current SCI rehabilitation research, the use of technology to augment physical interventions was found to be common; however, the feasibility, appropriateness, meaningfulness and economic impact of these new therapies require greater consideration. Ongoing dialogues between clinicians and researchers can ensure that new technologies and ideas are vetted rigorously while informing changes to practice that will maximize outcomes for individuals with SCI.

Additional file

Additional file 1: (91.2KB, xlsx)

Supplementary Info - Data Extraction Table JNER. (XLSX 91 kb)

Acknowledgements

We thank Professor Molly Verrier and Dr. Jean-François Lemay for providing comments on an earlier version of this manuscript.

Funding

This work was funded by a grant to KEM from the Craig H. Neilsen Foundation.

Availability of data and materials

All data generated or analysed during this study are included in this published article and its Additional file 1.

Author’s contributions

MS and KEM completed the environmental scan. KEM, MS and JZ contributed to the interpretation of the information provided by the environmental scan. KEM was a major contributor in writing the manuscript. KEM, MS and JZ read, edited and approved the final manuscript.

Abbreviations

ABT

Activity-based therapies

BWSTT

Body weight-supported treadmill training

DBS

Deep brain stimulation

FAME

Feasibility, Acceptability, Meaningfulness, Effectiveness, Economic Evidence

FES

Functional electrical stimulation

LE

Lower extremity

PNS

Peripheral nerve stimulation

QALY

Quality-adjusted-life-years

rTMS

repetitive transcranial magnetic stimulation

SC

Spinal cord

SCI

Spinal cord injury

tDCS

transcranial direct current stimulation

TT

Treadmill training

UE

Upper extremity

Ethics approval and consent to participate

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Footnotes

Electronic supplementary material

The online version of this article (10.1186/s12984-018-0386-7) contains supplementary material, which is available to authorized users.

Contributor Information

Kristin E. Musselman, Phone: 416-597-3422, Email: Kristin.Musselman@uhn.ca

Meeral Shah, Email: meeral@live.ca.

José Zariffa, Email: Jose.Zariffa@utoronto.ca.

References

  • 1.Behrman AL, Bowden MG, Nair PM. Neuroplasticity after spinal cord injury and training: an emerging paradigm shift in rehabilitation and walking recovery. Phys Ther. 2006;86:1406–1425. doi: 10.2522/ptj.20050212. [DOI] [PubMed] [Google Scholar]
  • 2.Lovely RG, Gregor RJ, Roy RR, Edgerton VR. Effects of training on the recovery of full-weight-bearing stepping in the adult spinal cat. Exp Neurol. 1986;92:421–435. doi: 10.1016/0014-4886(86)90094-4. [DOI] [PubMed] [Google Scholar]
  • 3.Fung J, Stewart JE, Barbeau H. The combined effects of clonidine and cyproheptadine with interactive training on the modulation of locomotion in spinal cord injured subjects. J Neurol Sci. 1990;100:85–93. doi: 10.1016/0022-510X(90)90017-H. [DOI] [PubMed] [Google Scholar]
  • 4.Onifer SM, Smith GM, Fouad K. Plasticity after spinal cord injury: relevance to recovery and approaches to facilitate it. Neurotherapeutics. 2011;8:283–293. doi: 10.1007/s13311-011-0034-4. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 5.Langan J, Subryan H, Nwogu I, Cavuoto L. Reported use of technology in stroke rehabilitation by physical and occupational therapists. Disabil Rehabil: assist Technol. E-pub Aug. 2017:16. [DOI] [PubMed]
  • 6.Hochstenbach-Waelen A, Seelen HAM. Embracing change: practical and theoretical considerations for successful implementation of technology assisting upper limb training in stroke. J Neuroeng Rehabil. 2012;9:52. doi: 10.1186/1743-0003-9-52. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 7.Auchstaetter N, Luc J, Lukye S, Lynd K, Schemenauer S, Whittaker M, Musselman KE. Physical therapists’ use of functional electrical stimulation for clients with stroke: frequency, barriers, and facilitators. Phys Ther. 2016;96:995–1005. doi: 10.2522/ptj.20150464. [DOI] [PubMed] [Google Scholar]
  • 8.Pearson A, Wiechula R, Court A, Lockwood C. The JBI model of evidence –based healthcare. Int J Evid Based Healthc. 2005;3:207–215. doi: 10.1111/j.1479-6988.2005.00026.x. [DOI] [PubMed] [Google Scholar]
  • 9.Booth A, Cantrell A, Preston L, Chambers D, Goyder E. What is the evidence for the effectiveness, appropriateness and feasibility of group clinics for patients with chronic conditions? A systematic review. Southhampton (UK): NIHR journals. Library. 2015; [PubMed]
  • 10.Graham P, Evitts T. Thomas-MacLean R. Environmental scans: how useful are they for primary care research? Can Fam Physician. 2008;54:1022–1023. [PMC free article] [PubMed] [Google Scholar]
  • 11.Andersen KD. Targeting recovery: priorities of the spinal cord injured population. J Neurotrauma. 2004;21:1371–1383. doi: 10.1089/neu.2004.21.1371. [DOI] [PubMed] [Google Scholar]
  • 12.Kleim JA, Jones TA. Principles of experience-dependent neural plasticity: implications for rehabilitation after brain damage. J Speech Lang Hear Res. 2008;51:S225–S239. doi: 10.1044/1092-4388(2008/018). [DOI] [PubMed] [Google Scholar]
  • 13.National SCI Statistical Centre 2016. https://www.nscisc.uab.edu/Public/Facts%202016.pdf (2016). Accessed 30 Oct 2017.
  • 14.World Health Organization . ICF: international classification of functioning, disability and health. Geneva: World Health Organization; 2016. [PubMed] [Google Scholar]
  • 15.Boninger M, French J, Abbas J, Nagy L, Ferguson-Pell M, Taylor SJ, Rodgers M, Saunders N, Peckham H, Marshall R, Sherwood A. Technology for mobility in SCI 10 years from now. Spinal Cord. 2012;50:358–363. doi: 10.1038/sc.2011.165. [DOI] [PubMed] [Google Scholar]
  • 16.Ernst E, Pittler MH. Efficacy or effectiveness? J Intern Med. 2006;260:488–490. doi: 10.1111/j.1365-2796.2006.01707.x. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1: (91.2KB, xlsx)

Supplementary Info - Data Extraction Table JNER. (XLSX 91 kb)

Data Availability Statement

All data generated or analysed during this study are included in this published article and its Additional file 1.

Rehabilitation technologies and interventions for individuals with spinal cord injury: translational potential of current trends (2024)

References

Top Articles
Latest Posts
Recommended Articles
Article information

Author: Arline Emard IV

Last Updated:

Views: 5820

Rating: 4.1 / 5 (72 voted)

Reviews: 95% of readers found this page helpful

Author information

Name: Arline Emard IV

Birthday: 1996-07-10

Address: 8912 Hintz Shore, West Louie, AZ 69363-0747

Phone: +13454700762376

Job: Administration Technician

Hobby: Paintball, Horseback riding, Cycling, Running, Macrame, Playing musical instruments, Soapmaking

Introduction: My name is Arline Emard IV, I am a cheerful, gorgeous, colorful, joyous, excited, super, inquisitive person who loves writing and wants to share my knowledge and understanding with you.