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To cite: van Breda E,Verwulgen S, Saeys W, et al.Vibrotactile feedback as atool to improve motorlearning and sportsperformance: a systematicreview. BMJ Open SportExerc Med 2017;3:e000216.doi:10.1136/bmjsem-2016-000216
EB and SV contributedequally.
Accepted 3 May 2017
1Faculty of Medicine andHealth Sciences, Departmentof Rehabilitation Sciencesand Physiotherapy(MOVANT), University ofAntwerp, Antwerp, Belgium2Product Development,Faculty of Design Sciences,University of Antwerp,Antwerp, Belgium
Correspondence to
Dr Eric van Breda; eric.vanbreda@uantwerpen.be
Vibrotactile feedback as a tool toimprove motor learning and sportsperformance: a systematic review
Eric van Breda,1 Stijn Verwulgen,2 Wim Saeys,1 Katja Wuyts,1 Thomas Peeters,2
Steven Truijen1
ABSTRACTBackground Evidence concerning the use ofvibrotactile feedback for acquiring and learning newmotor skills is limited. Although various concepts andapplications for tactile feedback have been proposed,little is known about the suitability of this feedbackmechanism in sports training.Aim The goal of this systematic review was to gatherknowledge on the efficacy of the use of vibrotactilefeedback in improving sports performance skills.Design Systematic review.Methods Comprehensively searched databases were:PubMed, Cochrane and Web of Science. Studiesinvestigating the effects of using vibrotactile feedbackin sports training in healthy subjects were included inthis review.Results No consensus was found regarding thepositive effectiveness on performance using vibrotactilefeedback in a sports context. No evidence was foundthat the addition of tactile feedback is effective foracquiring new motor skills. None of the studies show asignificant learning effect.
INTRODUCTIONWhen an athlete performs a designatedmovement (motor task), any attempt isneurophysiological evaluated by scanningthe information originating from intrinsicfeedback (IFB) systems such as visual, audi-tory, proprioceptive and/or tactilefeedback (TFB). Those feedback(FB) systems analyse and adjust extremityposition either in real time (concurrent FB)or store the information during post-taskevaluation (terminal FB).1 Thus IFB leadsto the information regarding the outcomeof the motor task (knowledge of results) andprovides information of the entire processof a motor task (knowledge of perfor-mance).1 2 The only IFB system that is indirect contact with the environment istactile sensory system, known as TFB. TFBallows us to interact with the environmentthrough specific sensors in the skin. Theysense vibration, pressure, touch, textureand so on. TFB is complex and is primarily
composed of a skin sensation, enablingsubjects to localise and recognise individualtactile cues and collaborates closely with theproprioceptive and kinaesthetic system,that is, body part position recognition.3
Interestingly, TFB is the only FB systemthat is bidirectional, that is, it interacts withthe environment and simultaneously sensesand processes such interactions.4–6
Although TFB is essential for movement-controlled actions, it can also be adisturbing factor by creating a kind ofsensory overload mainly because it can alsobe handled consciously.7
In contrast to IFB, augmented feedback(AFB) serves as an add-on to the task-intrinsic information and is exclusivelydelivered by external cues.2 To date, it isimpossible to consider modern sportstraining, but also rehabilitation of certainpatient groups, without the use of AFB.AFB comes from external sources,for example, trainers/coaches, electronicdevices (displays, sounds), spectators and
What is already known?
" Motor tasks are controlled by intrinsic feedbackmechanisms.
" Augmented feedback (verbal instructions) inlearning new motor tasks is important in sports.
What are the new findings?
" The use of vibrotactile feedback in severalmedical and non-medical areas has well beenestablished.
" Vibrotactile feedback as feedback tool in sportshas not yet been supported by scientificevidence.
" There lies a huge potential for sports science tostudy feedback mechanisms by using vibrotactilefeedback as intervention tool.
van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216 1
Open Access Review
recently also haptic systems (robots, vibrotactile(VT) actuators), or a combination thereof.3 AFB hasalso been shown to play an important role in learningnew motor tasks by enhancing the effect of IFB.5 8 Thiscan be provided verbally (a coach provides detailedspoken instructions), visually (a coach demonstrates thespecific task) or haptic (a coach guides part of thetrajectory of the movement by touching the subject atkey parts of the motor task) cues. Mostly, however,AFB is offered after completion of a motor task, asterminal FB. Although it has been shown that terminalFB can play an important role in the learning processof motor tasks, the major drawback of this type of FB isthat it only provides information on the outcome ofthe motor task but not real time on the process as inconcurrent FB.5 Nowadays, technological progressallows us to provide information to an athlete inreal time. One of such methods is vibrotactile feedback(VTFB). During VTFB, a signal is generated by anactuator that applies vibrational stimuli to the skinguided by information on position of an extremity.9
VTFB is a form of concurrent FB and information canbe delivered by varying temporal parameters infrequency, amplitude, waveform and/or duration.10
The tight coupling between motor task and theresulting VTFB stimuli requires a minimal latency.11
Instant and real-time augmented VTFB makes itfeasible to provide spatial proprioceptive informationduring a complex motor task.12 In this sense, VTFBcan thus be used to guide a motor task and provideinstant FB. VTFB is, from a neurophysiological pointof view, an interesting source of FB, since it can bypassthe athletes’ visual FB system. The relatively small, low-weight and wireless potential makes it an excellentFB tool.3
Prior to the use of VTFB, consistent metaphors needto be learnt. Amemiya et al suggested that wearableVTFB devices should create realistic sensations.13 Inthat light, Spelmezan and Ziefle distinguished twotypes of encoding metaphors: a push and a pull meta-phor.14 The pull metaphor means that the extremity ofa subject reacts to a signal by moving towards the stim-ulus, whereas the push metaphor means that it pullsaway from the stimulus.The major aim of this present systematic review is to
evaluate the definitions, methodologies and use ofFB systems for learning motor tasks in sports. To thebest of our knowledge, this is the first systematic reviewon VTFB systems within sports.
METHODSDesignThis systematic review was conducted in accordancewith the PRISMA (Preferred Reporting Items forSystematic Reviews and Meta-Analyses) guidelines,which is an updated statement addressing the concep-tual and methodological issues of the originalQUOROM (Quality of Reporting of Meta-Analyses) statement.15
Search strategyPICO(S) components were used to establish theresearch question. This PICO(S), along with the corre-sponding eligibility criteria, is shown in table 1.To complete this review, three electronic databases
were used. PubMed (http://www.ncbi.nlm.nih.gov/pubmed/), Web of Science (WOS; https://webofknowl-edge.com/) and the Cochrane database (http:// www.cochranelibrary.com) were searched for peer-reviewedarticles.
Table 1 PICOS and eligibility criteria
Inclusion criteria Exclusion criteria
P Adults
Adolescents
Athletes or healthy subjects who practise sports regularly
Children (<10 years)
Elderly (>65 years)
Non-athletes
Unhealthy subjects
Any pathology related to movements
Animals
I VTFB —
C Non-VTFB —
O Heart rate
Joint angles
Motor patterns
Movement variability
S Randomised clinical trials, randomised controlled trials, clinical
trial, case reports, cohort study
Non-English, Dutch, French or German,
systematic review, meta-analysis
VTFB, vibrotactile feedback.
2 van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216
Open Access
Table
2Databasesearchstrategy
Database
Searchquery
October2015
March
2017
PubMed
(‘Feedback,Sensory’[Mesh]OR‘sensory
feedback’[AllFields]OR‘Touch’[Mesh]OR‘hapticfeedback’[AllFields]OR‘VT
feedback’[AllFields]OR‘electro-opticalfeedback’[AllFields])AND
((‘Athletes’[Mesh])OR‘athletes’[AllFields])ORbobsled[All
Fields]OR‘w
intersports’[AllFields]OR‘sports’[MeSH
Term
s]OR‘sport’[AllFields]OR‘rowing’[AllFields])AND(‘Learning
Curve’[Mesh]OR‘learningcurve’[AllFields]ORperform
ance[AllFields]OR‘ReactionTim
e’[Mesh]OR‘reactiontime’[AllFields]
ORaerodynamics[AllFields]ORsynchronization[AllFields]OR‘posture’[MeSH
Term
s]OR‘posture’[AllFields]OR‘m
otor
learning’[AllFields]OR‘SpatialLearning’[Mesh]OR‘SpatialLearning’[AllFields]OR‘Practice(Psychology)‘[M
esh]OR‘Practice
(Psychology)‘[AllFields]OR‘M
otorSkills’[Mesh]OR‘M
otorSkills’[AllFields]OR‘AthleticPerform
ance’[Mesh]OR‘Athletic
Perform
ance’[AllFields]OR‘PsychomotorPerform
ance’[Mesh]OR‘PsychomotorPerform
ance’[AllFields]OR‘Touch
Perception’[Mesh:noexp]OR‘TouchPerception’[AllFields]OR‘Sensory
Thresholds’[Mesh]OR‘Sensory
Thresholds’[AllFields]
OR‘DifferentialThreshold’[Mesh]OR‘DifferentialThreshold’[AllFields]OR‘latency’[AllFields])
211
214
Cochrane
(‘Sensory
feedback’OR‘Touch’OR‘hapticfeedback’OR‘VTfeedback’OR‘electro-opticalfeedback’)AND
(‘athletes’OR
‘bobsled’OR‘w
intersports’OR‘sports’OR‘rowing’)AND(‘posture’OR‘learningcurve’OR‘perform
ance’OR‘reactiontime’
OR‘aerodynamics’OR‘synchronization’OR‘m
otorlearning’OR‘SpatialLearning’OR‘Practice(Psychology)’OR‘M
otorSkills’
OR‘AthleticPerform
ance’OR‘PsychomotorPerform
ance’OR‘TouchPerception’OR‘Sensory
Thresholds’OR‘Differential
Threshold’)
77
Webof
Science
TS=((‘sensory
feedback’OR‘Touch’OR‘hapticfeedback’OR‘VTfeedback’OR‘electro-opticalfeedback’)AND(‘athletes’OR
‘bobsled’OR‘w
intersports’OR‘sports’OR‘rowing’)AND(‘learningcurve’OR‘perform
ance’OR‘reactiontime’OR
‘aerodynamics’OR‘synchronization’OR‘posture’OR‘m
otorlearning’OR‘SpatialLearning’OR‘Practice(Psychology)’OR
‘MotorSkills’OR‘AthleticPerform
ance’OR‘PsychomotorPerform
ance’OR‘TouchPerception’OR‘Sensory
Thresholds’OR
‘DifferentialThreshold’OR‘latency’))
74
75
van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216 3
Open Access
The Cochrane was used to find relevant clinical trialswithout date restrictions as search option. Using theadvanced search option, a selection was made to findclinical trials only. Conference papers were excluded.FB conditions where VTFB is used to only roboticallyguide someone, that is, the subject playing a passiverole, were also excluded from this review, along withFB conditions where VTFB is used as sensorysubstitution.In addition, we manually searched for relevant
articles based on article citations and reference lists inthe PubMed and WOS databases. The articles foundwere extracted and organised in EndNote Online.Duplicates were removed manually. The first searchwas performed in October 2015 and the date of thelast search was on 30 March 2017.The search strategy is shown in table 2.
Study selectionAfter implementation of the research strategy in alldatabases and the execution of the manual search,articles were extracted and organised in EndNoteOnline. Duplicates were deleted by hand. Theremaining articles were transferred to an Exceltemplate published by the KCE-Belgian Health CareKnowledge Centre (http://kce.fgov.be/). Two hundredand ninety-six (296) articles from the three used data-bases, 321 studies selected for screening and 25records from other sources (30 March 2017) weresequentially included or excluded according to theeligibility criteria. Two reviewers (KW and TP)performed eligibility assessment independently in anunblinded standardised manner.Thus, the inclusion criteria were:
1. athletes or healthy subjects who practise sportsregularly;
2. VTFB or haptic FB;3. heart rate (HR), joint angles, motor patterns, move-
ment variability;4. randomised clinical trials, randomised
controlled trials, clinical trial, case reports, cohortstudy, and so on;
5. full text written in English, Dutch, German andFrench;
6. study subjects are adolescents or adults.
Exclusion criteria were:
1. non-healthy or pathological population and animals;2. children (<10 years of age) and elderly (>65+);3. other languages than those mentioned above;4. meta-analysis, systematic reviews.
Experiments by Pressley and Ghatala indicated thatchildren younger than 10 years of age are less accu-rately aware of FB results. Consequently, this set ourlower age limit in our search strategy.16 The same goesfor the upper limit in adults as has been shown byRodrigue et al.17
The systematic screening of the articles was carriedout in two different phases. First, all search resultswere screened based on title and abstract in a prelimi-nary screening. If citations were considered potentiallyeligible and relevant, and if both reviewers (KW andTP) independently had agreed, full-text articles wereobtained. In the second phase, full-text articles wereevaluated. Detailed evaluation of the full-text publica-tion was necessary for 47 articles. Disagreementsbetween reviewers were resolved by consensus. If noconsensus could be reached, a third reviewer (SV)would decide.
Data extractionTwo reviewers (KW and TP) independently performeddata extraction by selecting relevant data and inte-grating it into two databases. The two databases werecompared and integrated into a final extraction table.Again, disagreements were resolved through discussionbetween KW and TP, and in case of disagreement athird author (SV) was asked to make a final judgement.None of the authors were contacted for further infor-mation when information was missing or unclearlyreported. The reason for the latter was that non-peer-reviewed unpublished information would, amongothers, hamper the systematic review process andcould affect the quality of this paper as such.
Table 3 EBRO classification of study results and recommendations: classification of the study results according to the
level of evidence
A1 Meta-analyses (systematic reviews) which include at least some randomised clinical trials at quality level A2 that
show consistent results between studies
A2 Randomised clinical trials of a good methodological quality (randomised double-blind controlled studies) with
sufficient power and consistency
B Randomised clinical trials of a moderate methodological quality or with insufficient power, or other non-randomised,
cohort or patient–control group study designs that involve intergroup comparisons
C Patient series
D Expert opinion
EBRO, Evidence-Based Richtlijn(guideline)Ontwikkeling(development).
4 van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216
Open Access
Items extracted from the studies were study design,age and number of subjects included, study characteris-tics (including branch of sports or movement studied,setting and FB conditions), VTFB conditions (includingnumber of vibrotactors, vibrotactor placement,vibrating frequency, stimuli duration, encoding signalsand possible bandwidth used), type of outcome meas-ures, and follow-up or retention and finally mainresults.
Risk of bias assessmentTwo independent reviewers (KW and TP) independentlyassessed all included articles.Suitability of randomisation and concealment of alloca-tion, blinding of patients, healthcare providers, datacollectors, and outcome assessors, and extent of loss tofollow-up were determined by the two above-mentioned reviewers using the PEDro (PhysiotherapyEvidence Database) scale. According to de Morton,18
the PEDro scale is a valid tool to measure the method-ological quality of clinical trials.The risk of bias was assessed by the same authors
(KW and TP) who performed the systematic search ofliterature. The two authors performed the assessmentof methodological quality independently. Findings
were compared for agreement but in case of disagree-ment, a third judgement was in all cases obtained byone of the other coauthors (SV). Agreement betweenthe two reviewers concerning the scoring of methodo-logical quality was determined by the Cohen’s kappa.Cohen’s kappa coefficient is a statistic measure forinter-rater agreement for qualitative items. In all cases,disagreements were resolved by discussion.Scores were assigned based on meeting up with the
criteria. A maximum possible score of 10 (low risk ofbias) could be reached. Scores 6–10 were regarded ashigh-quality studies, 4–5 as fair quality and 3 or loweras poor quality. Studies with a risk of bias assessmentscore of 3 or less were considered poor and theircontribution to results was weighted as half.Evidence was graded according to EBRO (Evidence-
Based Richtlijn[guideline]Ontwikkeling[development])recommendations (table 3).19 EBRO is an initiative ofthe Dutch Cochrane Centre and the Dutch Institute forHealthcare Improvement (CBO, http://www.cbo.nl), amember of the Guidelines International Network.
Data analysisSince the average quality of the studies was poor, aquantitative or meta-analysis was not feasible. We tried
Figure 1 Flow chart of the search strategy and study selection process. WOS, Web of Science.
van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216 5
Open Access
Table
4Data
extractiontable
Study
Design
Study
population
(n)
Mean
age
(years)
Movement
orbranchof
sports
Setting
Feedback
conditions
Training
(Noof
days)
Retention
Outcome
measures
Main
results
Eid
etal21
Clinicaltrial
10
—Treadmill
running
Lab
VTFB*
Nike+
SportBand
(VFB)
Nodevice
1None
HR
VTFB="efficient
regulatingHR(#
fluctuations)
VTFB=biggersteps,
breathing"efficient
FasterHRrecovery
Lieberm
anand
Breazeal22
Clinicaltrial
40
—5dfarm
motions
Lab
VFB
VVTFB
1None
Jointangle
error
Average
subjecterror
(RMSE)
VVT=overall#errorof
21%
(sig)
Hingejointerrors
#(sig),rotationaljoint6¼
# 15%"perform
ance,
7%
accelerate
learning
Sigristetal26
Randomisedcontrolled
trial
F:8;M:28
Total:36
28±3.7
(22–40)
Rowing
Lab
Concurrent
VFB
Concurrent
AFB
Concurrent
HFB
Term
inalFB
(control)
3Short
term
:start
days2and
3 Longterm
:1day
1week
Temporal
error
Spatialerror
RMSE
Error
intiming
Errorin
velocityratio
Movement
variability
H=larger+",
movements
(sig)FB+
nFBV="perform
ance
withFB+#cognitive
demanding
Tearly"perform
ance,
but"temporalerror
H=perform
anceFB>
nFB(fasterexecution
innFB)
H=#temporaland
velocityerror
Term
inalFB="
effectivethan
concurrenttypeofFB
Spelm
ezanetal29
Trial
1Exploratory
study
F:8;M:12
Total:20
25.25
(22–28)
—Lab
Tactile
stimulation†
1None
Description
ofperceived
FB
""Variety
inresponses
(50/50:pushvspull)
SP=slower
processing+"
attention
Trial
2Clinicaltrial
F:4;M:14
Total:18
(19–30)
Wii-balance
board
(slalom)
Lab
Random
tactile
motion
instructions
11day
%Pattern
recognition
High%
pattern
recognitionrelaxed+
mobile
Nosig
,perform
ance
retentionversustest
Trial
3Clinicaltrial
F:4;M:6
Total:10
(23–28)
Snowboarding
Reality
based
VTFB*
Audio
instructions
1None
RT
%Pattern
recognition
Perception
audio
instructions
FasterRTto
tactile
instructions
Audio
instructions
easierto
interpret
%RecognitionA>VT
(97%
vs87%
)
Con
tinued
6 van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216
Open Access
Table
4Continued
Study
Design
Study
population
(n)
Mean
age
(years)
Movement
orbranchof
sports
Setting
Feedback
conditions
Training
(Noof
days)
Retention
Outcome
measures
Main
results
28
Randomisedclinicaltrial
F:22
20.1±1.06
Rowing
Lab
DirectVT
positionalFB
Directn-
positionalFB
Delayedn-
positionalFB
1None
HR
Tim
ingof
knee/back
angle
Speed
VT:#HRovertests
("in
otherFBgroups)
Nosig
,in
speedand
timingbetw
eenFB
groups
Spelm
ezan23
Clinicaltrial
F:2;M:8
Total:10
(21–29)
Snowboarding
Reality
based
Verbal
instructions*
Verbal+VTFB
1None
System
recognition
accuracy
M(O
)%
Riding
mistakes
Verbal="effectivefor
learningnew
skills
VTFB+verbalFB="
cognitiveload
VTFB=effectivein
sim
ple
exercises
Jansenetal24
Clinicaltrial
F:7;M:8
Total:15
(19–25)
Wristrotation
Lab
SRT*
CRT
1None
RT
RTforL+Rrotations
EFR=mostintuitive(=
push)+#RT
vanderLinden
etal27
Randomisedcontrolled
trial
F:3;M:5
Total:8
25–30
Playingthe
violin
Reality
based
FB
Control
4Minim
um
1day
Proxim
al-
distal
deviation
Vertical
deviation
Sig
,pretestversus
test(VT:#proxim
al-
distaldeviation)
n-sig:testversuspost-
testfi
nolearning
effectC
andFB
Control:noobvious
overallprogress
25
Clinicaltrial
F:15;M:11
Total:26
23.2
(18–
49)
1–3dfarm
motions
Lab
VFB*
VVTFB
44days
RMSangle
error
Arm
angle
error
Motionerror
AverageRMSEVVT=
#for1dfmotion(sig)
VVT:larger#errorday
4(1
and3df)
VTFBdifficultto
interpretin
multiple
df
WorkloadVVT>V(but
sig
#overtraining)
Nosig
effectofFBin
retentionorprobetrial
*Within-subjectdesign.
†Betw
een-subjects
design.
AFB,auditory
feedback;CRT,choicereactiontime;df,degreesoffreedom;EFR,extrinsic
frameofreference;F,female;FB,feedback;HFB,hapticfeedback;HR,heartrate;L,left;M,male;
M(O
),systemslatency;nFB,non-feedbacktrials;n-positional,non-positional;n-sig,non-significant;R,right;RMS,rootmeansquare;RMSE,rootmeansquare
error;RT,reactiontime;sig,
significant;SP,sim
ultaneouspatterns;SRT,sim
ple
reactiontime;VFB,visualfeedback;VT,vibrotactile;VTFB,vibrotactile
feedback;VVT,visualandvibrotactile;VVTFB,visualandvibrotactile
feedback.
van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216 7
Open Access
to analyse the data from the included studies in afashion as has been proposed by Saw et al.20 However,because of the diversity in outcome parameters and inobjective data, we have not been able to perform suchanalysis. Therefore, the results of the individual studieswill be presented qualitatively.
RESULTSStudy selectionThe PRISMA flow diagram (figure 1) summarises ourstudy selection process. The initial search yielded 312results, of which 16 duplicates were deleted, leaving a
total of 296 studies. The manual search and repeatedsearch yielded a total of 25 extra studies, making atotal of 321 studies that were selected for screening.From the initial 296 studies, 274 were excluded basedon title and abstract. Subsequently, 38 studies wereexcluded based on full-text screening. Of the 25studies obtained by the manual and repeated searchperformed on 30 March 2017, a total of 14 wereexcluded based on title and abstract, and 6 on the full-text screening. Nine9 studies remained eligible for thisreview.
Table 5 Methodological scoring using the PEDro checklist and level of evidence of individual studies according to the
CBO guidelines
Study
Items Methodological
quality
Level of
evidence1* 2 3 4 5 6 7 8 9 10 11 Score**
Eid et al21 � ? ? ? � � � � + � � 1/10 Poor B
Lieberman and Breazeal22 � ? ? ? + ? ? + + + + 5/10 Fair B
Sigrist et al26 + + ? + ? ? ? + + + + 6/10 High B
Spelmezan et al29 Study
1
� + ? + + ? ? ? + � � 3/10 Poor C
Study
2
� � � � ? ? ? + + + + 4/10 Fair C
Study
3
� + ? � ? � ? + + + + 5/10 Fair B
Van Erp et al28 ? + ? + ? ? ? + + + + 6/10 High B/A2
Spelmezan23 � + ? � � + + + + + + 7/10 High B
Jansen et al24 ? � � + ? ? ? + + + + 5/10 Fair B
van der Linden et al27 � � ? + ? ? ? + + + + 5/10 Fair B
25 � + ? + ? ? ? + + + + 6/10 High B
Scoring by the PEDro scale:
+ = Yes
� = No
? = Too little information or doubtable.
Legend:
1: Eligibility criteria were specified.
2: Subjects were randomly allocated to groups (in a crossover study, subjects were randomly allocated an order in which treatments were
received).
3: Allocation was concealed.
4: The groups were similar at baseline regarding the most important prognostic indicators.
5: There was blinding of all subjects.
6: There was blinding of all therapists who administered the therapy.
7: There was blinding of all assessors who measured at least one key outcome.
8: Measures of at least one key outcome were obtained from more than 85% of the subjects initially allocated to groups.
9: All subjects for whom outcome measures were available received the treatment or control condition as allocated or, where this was not
the case, data for at least one key outcome were analysed by ‘intention to treat.’
10: The results of between-group statistical comparisons are reported for at least one key outcome.
11: The study provides both point measures and measures of variability for at least one key outcome.
PEDro scores:
High quality = score 6–10
Fair quality = score 4–5
Poor quality = score �3
*Item 1 pertains for the external validity, thus is not considered for the final score.
**Poor quality = PEDro score �3.
CBO, Dutch Institute for Healthcare Improvement; PEDro, Physiotherapy Evidence Database.
8 van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216
Open Access
The majority of the studies were excluded based onintervention and population, 63% and 20%, respec-tively. Twenty20 studies were excluded based on itsstudy design and 24 based on outcome. Finally, three3
studies were excluded based on subject, eight8 studieson language and four4 studies were excluded based onage of the population. The majority of full-text exclu-sions were based on intervention.
Study characteristicsFor each included study, the characteristics of dataextraction are shown in table 4. All nine9 studies werepublished in English and could be designated as clin-ical study designs with VTFB as (one of) theintervention(s). The majority of the studies involvedsimple clinical trials21–25 whereas two studies26 27
involved a randomised controlled trial. Only one studycould be designated as a randomised clinical trial.28
The study of Spelmezan et al29 consists of one explor-
atory clinical trial with an open response paradigm andtwo clinical trials, one of which was performed in areality-based context. Two studies investigated theeffects of VTFB during rowing, two during snow-boarding, one focused on treadmill running and twoduring a simple arm movement.26 28 One study investi-gated the effects of VTFB during an artistic skill.27
In two studies23 27 and in one of the trials of Spel-mezan et al,29 the experiments were done in a realrather than a laboratory setting.VTFB was compared with other FB modalities in the
majority of studies, except for the study of Jansenet al
24 and in the first two trials of Spelmezan et al.29 Inthe latter, VTFB was the only intervention. Outcomeparameters differed between all studies. The mainoutcome parameters were joint angle error, root meansquare error (RMSE), percentage of correct patternrecognition, reaction time and HR. Secondary andadditional outcome parameters included temporal andspatial errors, timing errors and subjective descriptionof perceived FB. In five studies,22 23 25 26 29 partici-pants’ subjective impression on the FB modalities wasassessed using a questionnaire or interview. Durationof the intervention, that is, number of training days,ranged from 1 to 4days. Only four studies included aretention phase ranging from a 1-day retention test toa 1-week26 retention test.
Risk of bias within studiesTable 5 shows the methodological scoring and theassessment of the level of evidence.We found a significant Cohen’s kappa agreement
between the two authors who performed the reviewingconcerning the scoring of methodological quality(kw=0.983; p<0.001). In 97% of the cases, bothreviewers agreed. In all cases, disagreements wereresolved by consensus, and if no consensus could bereached by the two authors (KW and TP) a third authorwas asked (SV). Each item contributes one point to the
total PEDro score ranging from 0 to 10 points. Item 1is not considered for the final score as it relates toexternal validity. Of the nine included studies, one hada final PEDro score of 1,21 three22 24 27 had a finalscore of 5, three25 26 28 had a final score of 6 andone23 had a final score of 7. The study of Spelmezanet al
29 contains three trials of which one had a finalscore of 3, one had a final score of 4 and the third hada final score of 5. The overall quality of the includedstudies was fair to excellent, with the exception of thestudy of Eid et al (score 1)21 and the first trial of theSpelmezan et al’s study (score 3).29 Most studies wererated with a lower score based on blinding andrandomisation.
Results of individual studiesThe effects of VTFB in regulating optimal training intensityEid et al studied the effectiveness of VT stimuli toadjust exercise intensity.21 A within-subject design wasused to compare ‘training with VTFB’ with no deviceand one with a Nike+ SportBand, using HR as themain outcome parameter. Unfortunately, only onesubject was presented, but based on VTFB was shownto be more efficient to regulate HR, showing fewerfluctuations and resulting in a smooth change inmethod by taking bigger steps and breathing moreefficiently. A faster HR recovery was found in theVTFB condition.
VTFB in learning single and multiple degrees of freedom ofarm movements and initiating wrist rotationsLieberman and Breazeal22 and Bark et al
25 studiedwhether VTFB, based on the push protocol andsensory saltation, accelerates learning of single andmultiple degrees of freedom (df) arm movements andreduces motion errors. Lieberman22 compared visualFB (n=20) with the combination of visual FB andVTFB (n=20). They found that the addition of VTFBto motor training induces significant change in perfor-mance: a reduction in real-time errors by up to 27%and an improvement of learning rate by up to 23%;with a steady state in learning errors by 27% overflexion joints. Subjects with the combinationFB showed a significant higher level of correcting theirmotions in comparison to those without TCB. Nosignificant loss of comfort through the addition of thewearable has been reported by the subjects.In line with the studies of Lieberman et al,22 Bark
et al25 used a within-subject design to compare visual
FB with the combination of visual FB and VTFB. Theyreported that RMSE was significantly lower for thecombination group (15.7�
±6.5�) in comparison to thevisual only group (17.1�
±6.4�) for learning 1 df motion,but not for 2 or 3 df motions. In both groups, motionerrors decreased over the 4 days of training but nosignificant effect on joint angle error was found duringprobe or retention.
van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216 9
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Finally, Jansen et al studied whether VTFB was usefulin initiating wrist rotations and which stimulus locationprovided the fastest reaction time.24 They concludedthat an extrinsic reference frame in which the vibratorysignal ‘pulls’ the hand in the desired direction is mostintuitive.
Effectiveness of VTFB in a real sports contextSpelmezan et al conducted a within-subject study insnowboarding in which traditional verbal instructionsin combination with VTFB were compared with tradi-tional verbal FB only.23 Verbal instructions in themorning resulted in fewer mistakes compared withVTFB (p=0.044), whereas the opposite was true fortrials in the afternoon (p=0.014). Verbal instructionsoutweighed VTFB when practising new tasks. Suchresults are in line with another study of Spelmezan et al
in which snowboarders were provided with verbalFB instructions with or without VTFB.29 A fasterresponse time has been found for VTFB in comparisonwith verbal FB (p=0.01).The effectiveness of VTFB in learning a rowing task
was studied by Van Erp et al and Sigrist et al.26 28 VanErp et al
28 compared direct positional VTFB withdirect non-positional verbal FB and delayed non-posi-tional verbal feedback. Neither group showed alearning effect. The VT group showed a significant(p<0.02) decrease in HR over tests but no differencewas found between groups regarding timing andspeed. Sigrist et al
26 compared VTFB with verbalFB and auditory FB with a self-controlled terminal FB.Terminal self-controlled FB was found to be superiorto all types of concurrent AFB. Furthermore, a signifi-cant decrease in RMSE, temporal error and error invelocity ratio was found from baseline to retention indi-cating that VTFB is effective in enhancing temporalaspects, rather than spatial aspects of movement.Again, a guidance effect could be found, that is,decrease in performance in non-FB conditions.30
DISCUSSIONThe aim of the present review was to provide a moredetailed insight in the scientific literature concerningVTFB as a tool for sports performance enhancement.Only nine studies, based on the methodological criteriaset, were eligible for this review. The quality of thestudies was fair but the level of evidence was subop-timal. We conclude that, although VTFB has beenshown to be effective under some conditions, evidencefor its use as sports performance enhancement remainsscarce and challenging.10 11 31
Summary of evidenceVTFB has been used in navigation,32 aviation33 and inautomotive.34 It also found its way in virtual reality,gaming and in art.35 36 In healthcare, VTFB has beenused as a navigation tool in the visually
impaired subjects, as sensory substitution in the reha-bilitation of patients with stroke, and in vestibularimpaired subjects where it has been used as sensoryaugmentation.37 To the best of our knowledge, its usein sports practice is very limited. A reason for this isnot easy to provide but the limited number of scientificstudies in concordance with the broad range ofoutcome parameters and variability of the results inlaboratory setting may be the major cause of the lack ofuse in sports practice.Out of the nine studies eligible for final interpreta-
tion, only the studies of Spelmezan et al and van derLinden et al
23 27 29 addressed VTFB in a reality-basedcontext. For instance, van der Linden et al imple-mented the use of VTFB in real training situations forartists (violin players) whereas Spelmezan used snow-boarders as study population. Subjects in the laterstudy, however, stated that the VTFB instructionshindered normal movement because VT instructionswere randomly provided in time and the placement onthe body/limbs was reported to be frustrating. Thismight be one of the major reasons for athletes not touse VTFB devices on their body/limbs even if it mighthelp them to improve performance. These findings arein contrast with the findings of Lieberman et al,22 whoreported no loss of comfort during the application ofVTFB. The use of devices that differ in size, weightand position could play a major role in the acceptanceof VTFB in sports practice. Future studies shouldtherefore be designed such that VTFB does not inter-fere with normal movement by providing VTinstructions on suitable moments of VTFB.There is some evidence that VTFB is effective in
regulating exercise intensity during physical perfor-mance by keeping HR within aerobic limits.18 Byapplying VTFB, athletes could, based on their maximalHR, be guided by tactile information to perform at aless intense level and thus exercise more efficiently.Exercising with VTFB resulted in both short term andlong term, in a decrease in HR.22 The athletes in theirstudy who received TFB (ie, direct and positional)showed a decreased HR in the post-test as comparedwith the pretest whereas the athletes who did not getTFB showed an increase in HR. A plausible explana-tion for this HR effect was that athletes without VTFBwere less efficient in maintaining motor skills andmore than necessary adjustments in motor controlwere necessary. Therefore, it is reasonable to assumethat VTFB is effective in improving temporal move-ment aspects, but not spatial errors.26 These findingssupport the results of previous studies.38 39 Lastly,there is moderate evidence that VTFB instructionscould support the athlete in practising and fine-tuninga previously learnt movement. A second explanationfor an over-the-day decrease in HR is that VTFB is lessmental demanding.25 To date, no studies are presentthat support this idea.
10 van Breda E, et al. BMJ Open Sport Exerc Med 2017;3:e000216. doi:10.1136/bmjsem-2016-000216
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Some studies used joint angle errors as the mainoutcome parameter.19 22 This is somewhat surprisingsince joint angle is not necessarily the most importantoutcome parameter for motor performance, and assuch, athletic performance. Moreover, during a motortask, several joint angles should be taken into account,that when applying VTFB should provide simultaneousand multiple VTFB signals.23 25 27 The major draw-back, however, of some studies using VTFB as errorsignal is the lack of implementing an order orsequence in signals.22 28 Subjects are continuouslyprovided with FB signals which lead to overcorrectionof motor tasks/movements. Only a few scientific studiesthat used VTFB for motor task correction used moreaccurate and timed signals.21 25–27
Limitations of the current reviewThe quality and diversity of the studies made it impos-sible for us to do quantitative analysis of the results.The risk of bias of individual studies was overallmoderate to fair and because randomisation was inade-quate or lacking in the majority of trials, level ofevidence was moderate to weak. Furthermore, poorand incomplete reporting of study designs, patientpopulations and interventions made the interpretationand synthesis of the included studies much more diffi-cult and may have contributed to publication bias.Therefore, generalisation of the results to athletes isdifficult.Finally, the main limitation of this study is that the
context of VTFB and comparison between different FBmodalities and outcome measures for performancewere not the same across the studies, making a directcomparison between the outcome of these studiesdifficult.
CONCLUSIONSOur review suggests that VTFB, which has been used asapplication in medical and non-medical-based contexts(ie, patient groups, automotive, and so on), lacks scien-tific support for enhancement of sports performanceoutcomes. The inconsistency of findings and moderatelevel of support, as reported in the present study,hardly provide evidence to support the suspected role.More basic and applied studies are necessary towarrant its use in a sports context.
Contributors The study was planned by EvB, SV and ST. KW and TPconducted the literature search whereas SV was used as author in case ofdisagreements during selection. EvB and SV wrote the initial draft of themanuscript. EvB, SV, WS and ST discussed and revised the manuscripttogether and gave final approval for publication.
Competing interests None declared.
Provenance and peer review Not commissioned; externally peer reviewed.
Open Access This is an Open Access article distributed in accordance withthe Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license,which permits others to distribute, remix, adapt, build upon this work non-
commercially, and license their derivative works on different terms, providedthe original work is properly cited and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/
Correction notice This paper has been amended since it was publishedOnline First. Owing to a scripting error, some of the publisher names in thereferences were replaced with 'BMJ Publishing Group'. This only affected thefull text version, not the PDF. We have since corrected these errors and thecorrect publishers have been inserted into the references.
© Article author(s) (or their employer(s) unless otherwise stated in the text ofthe article) 2017. All rights reserved. No commercial use is permitted unlessotherwise expressly granted.
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