Rehabilitation of social cognition impairment after traumatic brain injury: a systematic review

Rodríguez-Rajo, P.; Leno Colorado, D.; Enseñat-Cantallops, A.; García-Molina, A.

doi:10.1016/j.nrleng.2018.07.013

Información del artículo

Resumen

Texto completo

Bibliografía

Descargar PDF

Estadísticas

Figuras (1)

Abstract

Introduction

Many studies have described the presence of difficulty processing and generating social behaviour in patients who have suffered a traumatic brain injury (TBI). These difficulties in social cognition (SC) deteriorate personal relationships in the family, at work, or in the community. However, therapeutic programmes aiming to improve SC continue to be an outstanding issue in clinical practice. We performed a systematic review of the existing literature on the recovery of SC in patients with TBI, assessing the methodological quality of the included studies and the therapeutic effectiveness of the rehabilitation strategies used.

Development

We performed a bibliographic search of papers published before June 2018 in the Medline/PubMed, Google Scholar, PsycINFO, and ClinicalTrials.gov databases. Of the 198 potentially relevant articles, 10 met our eligibility criteria. Two of the authors independently and blindly assessed the methodological quality of these studies using the PEDro scale.

Conclusions

The articles included in this systematic review essentially studied the effect of different interventions aimed at the rehabilitation of SC in patients with chronic TBIs. The analysis showed adequate methodological quality and an acceptable level of evidence. Future research should analyse the effect of these interventions in patients with TBIs in the sub- and post-acute phases.

Keywords:

Traumatic brain injury

Social cognition

Rehabilitation

Treatment

Neuropsychology.

Resumen

Introducción

Múltiples estudios han descrito la presencia de dificultades para procesar y generar conductas de tipo social en pacientes que han sufrido un traumatismo craneoencefálico (TCE). Tales dificultades, englobadas bajo el término genérico de cognición social (CS), provocan un deterioro en las relaciones personales, tanto a nivel familiar, como laboral o comunitario. No obstante, los programas terapéuticos dirigidos a la mejora de la CS continúan siendo una asignatura pendiente en la práctica clínica. El objetivo de este trabajo es realizar una revisión sistemática de la literatura existente sobre rehabilitación de la CS en pacientes con TCE, valorar su calidad metodológica y la efectividad terapéutica de las estrategias rehabilitadoras empleadas.

Desarrollo

Se realizó una búsqueda bibliográfica hasta Junio de 2018 en las bases de datos Medline/PubMed, Google Scholar, PsycInfo y ClinicalTrials.gov. De los 198 artículos potencialmente interesantes, diez cumplieron los criterios de elegibilidad. Dos de los autores evaluaron, de forma independiente y ciega, la calidad metodológica de los estudios incluidos en la revisión mediante la escala PEDro.

Conclusiones

Los artículos incluidos en esta revisión sistemática han estudiado esencialmente el efecto de diferentes intervenciones dirigidas a la rehabilitación de la CS en pacientes con TCEs en fase crónica. El análisis muestra que su calidad metodológica es adecuada y que el nivel de evidencia es aceptable. Se constata la necesidad de analizar el efecto de estas intervenciones en pacientes con TCEs en fase sub-aguda y post-aguda.

Palabras clave:

Traumatismo craneoencefálico

Cognición social

Rehabilitación

Tratamiento

Neuropsicología.

Texto completo

Introduction

Humans are set apart from other animals by our capacity for social interaction. While other mammals (eg, bonobos, wolves, and dolphins) also exhibit this behaviour, its highest evolutionary expression is in humans. In this sense, the human brain areas linked to social interaction present considerable ontogenetic development.1 One factor explaining this development is the fact that throughout our evolutionary history humans have lived in communities and have needed to cooperate and compete with our peers to survive, which has led to increasingly complex interactions.2 This fundamentally social conception of humankind is nothing new: in classical Greece, Aristotle postulated the “natural sociability” of humans, whom he considered a social animal in that we need other members of our species in order to survive.3

This feature is highly characteristic of humans and constitutes a subject of interest in cognitive psychology. The construct of social cognition (SC) was proposed to define the processes responsible for the coding and decoding of social life.4 This difficult-to-define construct represents a specialised domain of general cognition, and is involved in solving social problems or processing social behaviour. The studies conducted in the late 1970s by the ethologists Premack and Woodruff5 constitute a significant development in this field of study. These researchers observed that chimpanzees are able to solve problems by making inferences from the behaviour of other individuals. Premack and Woodruff coined the term “theory of mind,” defined as the ability to attribute mental states to others and to predict their behaviour. Subsequently, Baron-Cohen et al.6 proposed that impaired theory of mind is the origin of the difficulties experienced by people with autism spectrum disorders when theorising about the minds of others and attributing external mental states.

However, SC is not limited to theory of mind; rather, this cognitive construct encompasses various other processes. For Adolphs,7 SC is a complex construct involving the coexistence of mechanisms for perceiving, processing, and evaluating social stimuli, enabling representation of the social environment and equipping the individual to respond appropriately to the situation. Through SC, we are able to recognise another person’s emotional state, to empathise with them, to put ourselves in their position (taking their perspective), and to glimpse the “hidden” motives behind their actions.8 To summarise, SC involves 3 fundamental elements: affect recognition, mentalisation (or theory of mind), and emotional regulation. Therefore, SC is responsible for processing both the initial or basic elements of social interactions or exchange (eg, emotional perception and recognition), and more advanced or complex elements, such as attributional style (the intentionality or causality attributed to an individual’s behaviour).9

SC is also an area of interest in the field of cognitive neuroscience. An important example is the socio-emotional processing model proposed by Ochsner.10 According to this model, SC involves 5 constructs: 1) acquisition of social-affective values and responses from the stimuli processed (associative conditioning between stimulus and emotional value); 2) recognising and responding to social-affective stimuli (facial or prosodic affect recognition, etc); 3) low-level mental state/trait inference (empathy); 4) high-level mental state/trait inference (theory of mind); and 5) context-sensitive regulation systems (regulating one’s own judgements and behaviours). Each of these constructs would have a specific neuroanatomical and neurofunctional substrate.

SC impairment is common in numerous neurological and psychiatric disorders, including traumatic brain injury (TBI) and other forms of acquired brain injury (ABI),11,12 frontotemporal dementia,13,14 schizophrenia,15,16 and autism spectrum disorders, as mentioned above.6

Several studies have described facial affect recognition difficulties in patients with TBI.17,20 According to a meta-analysis by Babbage et al.,21 39% of patients with severe TBI present severe facial affect recognition difficulties, particularly with regard to negative facial expressions.22,23 These problems are not limited to facial cues: difficulties with perceiving emotional prosody are also reported.18,24 Patients with TBI also exhibit impairment of theory of mind. Martín-Rodríguez and León-Carrión25 conducted a meta-analysis focused on patients with ABI (TBI in approximately half of cases), corroborating the existence of these deficits. The authors report a significant correlation between presence of ABI and moderate or severe alterations in tasks assessing theory of mind. The fact that TBI is the leading cause of death in people younger than 45 years, and the main neurological cause of disability associated with long life expectancy,26 demonstrates the scale of the healthcare, economic, and social problem of the association between this type of injury and SC impairment.

At a functional level, it is indisputable that the difficulties discussed above affect the day-to-day lives and family environment of patients with TBI. According to McDonald,27 the affect recognition difficulties experienced by patients with severe TBI result in inability to respond appropriately to other people’s reactions, to interpret feedback from interlocutors on whether or not their behaviour is appropriate, and to fully understand communication with other people. The combination of these difficulties results in the deterioration of social, family, workplace, and community relationships, leading to distress on the part of the patient’s family members, unemployment, and social isolation.28 SC impairment worsens if patients with TBI remain untreated,29 resulting in significant (and increasing) economic and social problems. Despite the evident need to include interventions targeting SC in all neurorehabilitation programmes, this remains an outstanding issue in the treatment of patients with TBI. These interventions have yielded promising results in other clinical conditions, such as schizophrenia,30 autism spectrum disorders,31 and intellectual disability.32 In fact, a limited number of studies in the field of TBI have shown positive results with rehabilitation treatments for SC.33 These circumstances demonstrate the need to consider the rehabilitation of affect perception and recognition, as well as mentalisation, as an essential objective in the design of holistic neurorehabilitation programmes for these patients.

We deemed it important to conduct a systematic review of the literature on the rehabilitation of SC in patients with TBI, generating a summary of the different approaches used to date. Our objective is to identify which rehabilitative treatments have been used, the degree of evidence supporting them, and what types of patients may benefit from them, with a view to guiding the work of professionals involved in the treatment of these deficits.

Material and methodsLiterature search strategy

We searched for scientific articles on the Medline/PubMed, Google Scholar, PsycInfo, and ClinicalTrials.gov databases.

We used the following search terms, combined with the Boolean operators AND and OR, as follows: “social cognition” OR “affect recognition” OR “emotional recognition” OR “emotion perception” OR “social functioning” OR “emotional processing” OR “emotion recognition” OR “emotional prosody” AND “brain injury” AND “treatment.”

Results were not limited according to year of publication. Therefore, the period searched had no start date, and the end date was June 2018.

Selection criteria

Inclusion criteria were as follows: 1) articles published in English or Spanish; 2) samples of patients aged over 18 years and diagnosed with TBI; 3) focus on the treatment of SC in patients with TBI (at least in the majority of participants); 4) randomised clinical trials, case reports, or cohort studies; and 5) completed, published studies (specifically for studies published on ClinicalTrials.gov). We excluded studies meeting the following criteria: 1) studies including mainly patients with non-traumatic brain injury (eg, stroke or tumours); 2) studies not focusing on the rehabilitation of SC; 3) narrative or systematic reviews and meta-analyses; 4) theoretical articles and chapters of books.

Assessment of methodological quality

We evaluated the methodological quality and risk of bias of articles meeting the selection criteria using the validated Spanish-language version of the Physiotherapy Evidence Database (PEDro) scale.34

The PEDro scale includes 11 items evaluating various aspects related to internal and external validity and interpretability. We assessed all items but the first (selection criteria) to calculate the total PEDro score. Therefore, the maximum possible score was 10 points. Each study’s methodological quality was assessed using the classification proposed by the ERABI Research Group35 and rated as excellent (9-10 points), good (6-8), acceptable (4-5), or poor (< 4). We determined the level of evidence according to the system proposed by Sackett et al.36 (Table 1).

Table 1.

Levels of evidence.

Level	Study design	Description
Level 1a	RCT	More than one RCT scoring ≥ 6 on the PEDro scale. Including comparisons between subjects in randomised conditions and cross-over designs.
Level 1b	RCT	RCT scoring ≥ 6 on the PEDro scale
Level 2	RCT	RCT scoring < 6 on the PEDro scale
	Prospective controlled trial	Prospective controlled trial (not randomised)
	Cohort study	Prospective longitudinal study using at least 2 similar groups, one of which is exposed to a specific condition
Level 3	Case-control study	Retrospective study comparing conditions, including historic cohorts
Level 4	Pretest-posttest study	Prospective study with pre-treatment measurement, an intervention, and post-treatment measurement in one group of subjects
	Posttest only	Prospective intervention study including one or more groups with post-treatment measurement (no pre-treatment measurements or measurements establishing a baseline)
	Case series	Retrospective study, generally collecting data from a review of clinical cases
Level 5	Observational study	Cross-sectional analysis to interpret associations
	Clinical consensus statement	Expert opinion without explicit critical evaluation, based on physiology, biomechanics, or “basic principles”
	Case study	Pre-post study of a single case

RCT: randomised controlled trial.

Source: Sackett et al.36

The methodological quality of the studies reviewed was independently evaluated by 2 blinded researchers (PRR and DLC). Inter-rater agreement was evaluated by determining the intraclass correlation coefficient, calculated with version 18 of the MedCalc statistics package (https://www.medcalc.org/).

ResultsDescription of studies

The literature search of the 4 databases cited above yielded a total of 198 results meeting the search criteria. After eliminating duplicate results, 182 articles remained, 10 of which met the eligibility criteria and were read and analysed in full text. This final sample included 6 randomised clinical trials (RCT),33,37–41 one prospective controlled trial (PCT),42 and 3 case studies.43–45 Fig. 1 shows the review process followed, in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) model.46

Fig. 1.

Flow diagram showing the systematic review process.

(0.08MB).

The studies reviewed include a total of 260 participants, 146 of whom were included in experimental groups and 107 in control groups (75 patients with ABI [mainly TBI] and 32 healthy controls). The 7 remaining patients were described in case studies.43–45 Table 2 provides details of study design, sample characteristics, and the duration of interventions in each article.

Table 2.

Characteristics of the studies reviewed.

Study	Design	Sample	Age, years (SD)	Progression time, years (SD)	Treatment intensity and duration
Westerhof-Evers et al.37	RCT	N=59 TBIEG (TScEmo): 30 (72% M, 28% W)CG (CogniPlus): 29 (93% M, 7% W)	43.2 (13)43.8 (13)42.3 (14)	8.1 (8.2)7.1 (7.1)9.0 (9.2)	16-20 sessions; 1h/week
Winegardner et al.43	CS	1 TBI (M)1 stroke (M)	3746	2411	1 weekly 1-h session (6 weeks)
Neumann et al.38	RCT	N=71 TBIEG (FAR): 24 (97% M, 3% W)EG (stories): 23 (78% M, 22% W)CG: 24 (67% M, 33% W)	39.8 (12.0)41 (11.6)41.5 (11.6)39.5 (10.3)	10.3 (8.9)12.3 (1.7)13.2 (2.8)12.6 (2.7)	3 weekly 1-h sessions (3 weeks)
Williamson and Isaki44	CS	1 TBI (M)1 TBI (M)	5344	137	2 weekly 1-h sessions (3 weeks)1 weekly 1-h session (3 weeks)
McDonald et al.39	RCT	N=20 (16 TBI, 3 stroke, 1 other)EG: 10 (60% M, 40% W)CG: 10 (90% M, 10% W)	42.6 (11.2)44.5 (12.7)46.6 (10.1)	9.4 (7.7)10.4 (7.7)8.3 (8.0)	3 2-h sessions
McDonald et al.42	PCT	N=54 (22 TBI)EG: 22 TBI (73% M, 27% W)CG: 32 healthy controls (65% M, 35% W)	42.2 (12.6)45.4 (12.8)	10.8 (11.3)	Single 1-h session per condition (spontaneous/focus/mimic); 3h total
Radice-Neumann et al.40	RCT	N=19 ABI (17 TBI, 2 other)EG (FAR): 10 (90% M, 10% W)EG (stories): 9 (33% M, 67% W)	4347 (6.3)38 (14.3)	1216 (8.5)8 (7.3)	3 weekly 1-h sessions; 6 or 9 sessions total
Bornhofen and McDonald41	RCT	N=18 TBIEG (EL): 6EG (SIT): 6CG (WL): 6	43.7 (12.3)35.4 (14.0)31.2 (16.8)	5 (4.0)6.63 (4.6)12.35 (11.4)	1 weekly 2.5-h session (10 weeks)
Bornhofen and McDonald33	RCT	N=12 TBI (91% M, 9% W)EG: 5 (1 drop-out)CG (WL): 6	35.83 (13.0)29.2 (4.49)43.5 (14.43)	7.8 (6.01)6.6 (5.9)9.7 (6.2)	2 weekly 1.5-h sessions (8 weeks)
Guercio et al.45	CS	1 TBI (M)1 TBI (M)1 encephalitis (M)	192719	6 months3 months2 months	1 session of 15-30min duration per condition (4 conditions:label original pictures/label updated pictures/match updated to original picture/match original to updated picture)

ABI: acquired brain injury; CG: control group; CS: case study; EG: experimental group; EL: errorless learning; FAR: facial affect recognition; M: man; PCT: prospective controlled trial; RCT: randomised controlled trial; SIT: self-instruction training; TBI: traumatic brain injury; W: woman; WL: wait-list.

Methodological quality

Inter-rater agreement (intraclass correlation coefficient) for total PEDro scale score was 0.99 (95% confidence interval, 0.96-0.99). Tables 3 and 4 show total and item PEDro scores for each study according to both raters, the level of evidence, and the effect of the treatment applied. The methodological quality of 3 RCTs37,38,41 was excellent; the remaining 3had good methodological quality.33,39,40 The only PCT42 reviewed also showed good methodological quality. The methodological quality of the case studies43–45 could not be assessed with the PEDro scale: given the considerable risk of bias inherent to this type of study, administration of the scale is not recommended. None of the studies analysed is registered on the clinicalTrials.gov database or any other registry enabling the risk of bias to be checked.

Table 3.

Methodological quality (PEDro scale scores) of the studies reviewed.

	Study
PEDro score	Westerhof-Evers et al.37	Winegardner et al.43	Neumann et al.38	Williamson and Isaki44	McDonald et al.39	McDonald et al.42	Radice-Neumann et al.40	Bornhofen and McDonald41	Bornhofen and McDonald33	Guercio et al.45
1. Eligibility criteria specified	1	NA	1	NA	1	1	1	1	1	NA
2. Random allocation	1	NA	1	NA	1	0.5	1	1	1	NA
3. Concealed allocation	1	NA	1	NA	1	0.5	1	1	1	NA
4. Groups similar at baseline	1	NA	0	NA	0	1	0	1	1	NA
5. Participant blinding	1	NA	1	NA	1	0.5	1	1	0	NA
6. Therapist blinding	0	NA	0.5	NA	0	0	0	0	0	NA
7. Assessor blinding	0.5	NA	1	NA	1	0.5	0	1	0	NA
8. Less than 15% drop-outs	1	NA	1	NA	1	1	1	0.5	1	NA
9. Intention to treat analysis	1	NA	1	NA	1	1	1	1	1	NA
10. Between-group statistical comparisons	1	NA	1	NA	1	1	1	1	1	NA
11. Point measures and variability data	1	NA	1	NA	1	1	1	1	1	NA

1: both raters considered the study to meet this criterion; 0.5: disagreement between raters as to whether the study met the criterion; 0: both raters considered the study not to meet the criterion.

NA: not applicable.

Table 4.

Methodological quality, level of evidence, and effect of treatment for each study.

Study	PEDro score (rater 1/rater 2)	Methodological quality (PEDro)	Level of evidence	Effect of treatment
Westerhof-Evers et al.37	9/8	Excellent/good	1a	Positive
Winegardner et al.43	NA/NA	NA	5	Partially positive
Neumann et al.38	8/9	Good/excellent	1a	Partially positive
Williamson and Isaki44	NA/NA	NA	5	Positive
McDonald et al.39	8/8	Good	1a	Partially positive
McDonald et al.42	6/6	Good	2	Negative
Radice-Neumann et al.40	7/7	Good	1a	Positive
Bornhofen and McDonald41	9/8	Excellent/good	1a	Partially positive
Bornhofen and McDonald33	7/7	Good	1a	Positive
Guercio et al.45	NA/NA	NA	5	Partially positive

Treatment effects. Positive: treatment shows benefits; partially positive: treatment shows relative benefits; negative: treatment shows no benefits.

NA: not applicable.

Summary of results

The interventions applied in the different studies involved a combination of different treatments, including: focused attention (7 studies37–40,42,44,45), mimicry (4 studies37,38,40,42), errorless learning (3 studies33,39,41), self-instruction (3 studies33,37,41), massed and distributed practice (2 studies33,39), perspective-taking (2 studies37,43), vanishing cues (one study38), psychoeducation (one study37), and social skills training (one study37). Table 5 summarises the treatments used in each study.

Table 5.

Summary of the interventions used in each study.

	Focused attention	Mimicry	Errorless learning	Self-instruction	Massed and distributed practice	Perspective-taking	Vanishing cues	Psychoeducation	Social skills training
Westerhof-Evers et al.37	X	X		X		X		X	X
Winegardner et al.43						X
Neumann et al.38	X	X					X
Williamson and Isaki44	X
McDonald et al.39	X		X		X
McDonald et al.42	X	X
Radice-Neumann et al.40	X	X
Bornhofen and McDonald41			X	X
Bornhofen and McDonald33			X	X	X
Guercio et al.45	X

Westerhof-Evers et al.37 performed a study evaluating the effects of a multifaceted approach (Treatment for Social Cognition and Emotion Regulation; T-ScEmo) in patients with TBI. T-ScEmo aims to treat SC through strategies to improve perception of social information, social understanding or the ability to mentalise, and the ability to regulate social behaviour. The group receiving T-ScEmo (n=30) was compared to a control group (n=29) of patients who received computerised non-social cognitive training (CogniPlus). According to the results of the study, the multifaceted treatment is effective for improving aspects of facial affect recognition and theory of mind, and increased societal participation and the level of empathy in social relationships.

Winegardner et al.43 trained 2 patients with anger and irritability problems in perspective-taking. The authors hypothesise that the irritability problems in their patients, and in patients with ABI in general, are largely explained by a hostile attributional style in their interpretation of the intentionality of others’ behaviour. Treatment involves training in cognitive reappraisal strategies and perceptual positioning through video and role-playing. The authors compared Aggression Questionnaire-Short Form47 and Interpersonal Reactivity Index48 scores from before and after treatment against normative data. Both patients showed reduced aggressiveness after the intervention.

In the RCT by Neumann et al.,38 71 patients with moderate or severe TBI were allocated to receive either facial affect recognition training (focused attention and mimicry) (FAR group; n=24); emotional inferencing training through the use of stories (stories group; n=23); or online tasks addressing other aspects of cognition (control group; n=24). Patients were assessed immediately after completing treatment and at 3 and 6 months. Patients in the FAR group scored significantly better than controls on measures of facial affect recognition. No differences were detected between the control group and the stories group.

Williamson and Isaki44 reported the cases of 2 patients with chronic TBI who received rehabilitation focused on improving facial affect recognition. The treatment involved several exercises: identifying emotions through static facial expressions, reflecting on personal experience of emotions, identifying sarcasm and emotions in social stories, and role-playing. The intervention was applied over the telephone; this was the only study we identified that used telemedicine to treat SC. After treatment, both patients showed improvements in the assessment measures used.

The RCT by McDonald et al.39 addresses the recognition of affect in verbal communication. In that study, the experimental group included 10 patients with ABI (mainly TBI), and the control group included 10 patients with similar characteristics who were on the wait list for rehabilitative treatment. The authors aimed to assess the effectiveness of a brief treatment for the rehabilitation of prosodic emotion recognition. The treatment involved 3 group tasks of increasing difficulty and individual exercises for home practice. The activities focused on establishing a common emotional vocabulary by discussing the meaning of the 6 basic emotions described by Ekman49 and addressing in greater detail the adjectives and behaviours associated with each. Subsequently, the treatment aimed to improve patients’ ability to distinguish between prosodic patterns associated with the different emotions through modelling, audio analysis, role-play, and production games. While no statistically significant differences were observed between groups, individual analysis revealed significant improvement in prosody recognition.

Another study by McDonald et al.42 had less promising results. In this PCT, 22 patients with TBI underwent 2 interventions that have previously shown good results for patients with other conditions.50 Specifically, the researchers instructed patients to focus their attention on or to mimic relevant facial expressions. Both techniques were applied to 22 patients with TBI and 32 healthy controls. Two surprising findings were reported: no significant differences in facial affect recognition were observed between groups prior to treatment, and the TBI group showed no benefit with either of the interventions. The authors suggest that the findings may be explained by additional “consumption” of attentional resources arising from the use of these strategies in patients with severe cognitive deficits, which could have a detrimental effect on and interfere with affect recognition. This is the only study to report that the treatment applied to the experimental group had no beneficial effects.

Radice-Neumann et al.40 randomly allocated 21 patients with ABI (19 with TBI and 2 with other causes) to 2 experimental groups. The first group (FAR; n=10) received a treatment aiming to improve facial affect recognition by training patients to focus attention on relevant visual information and to analyse and understand their own emotional experiences. The other group (stories of emotional inference group; n=9) received specific training to identify emotional responses through contextual cues in stories, and were asked to relate these stories to emotional events from their own lives. Patients in the FAR group showed significant improvements in facial affect recognition, ability to describe how they or others would feel in a hypothetical scenario, and socio-emotional behaviour (as reported by family members). Members of the stories group showed less pronounced improvements, although they did show an increase in the ability to make emotional inferences about how they would feel in a given context or scenario. The results suggest that patients with ABI are able to relearn affect recognition skills.

Bornhofen and McDonald41 conducted an RCT assessing the usefulness and effectiveness of 2 types of treatment strategies in the rehabilitation of affect recognition impairment in patients with TBI. Participants were allocated to 3 intervention groups: errorless learning (n=6), self-instruction training (n=6), and a wait-list control group (n=6). The effectiveness of the treatments was evaluated according to patients’ ability to identify emotions through visual cues, using both static and audiovisual (video) materials, and through social inferences based on emotional behaviour. After the intervention, patients in both the errorless learning and the self-instruction training groups showed improved ability to recognise emotions in photographs of faces, although the improvement in social inferences was only significant in patients receiving self-instruction training. Caution should be exercised in the interpretation of these results due to the small sample size.

The same researchers conducted another RCT with 12 patients with chronic TBI.33 Patients were allocated either to the wait-list control group (n=6) or to receive an intervention involving the application of several rehabilitation techniques to improve affect recognition (n=5; 1 drop-out). The treatment involved training participants in the perception and interpretation of static and dynamic emotional cues. The intervention was structured as follows: interpreting conventional emotional contexts; interpreting static visual cues; interpreting dynamic uni- or multimodal cues; and training in social inferences based on emotional behaviour and situational cues. The treatment was based on errorless learning, self-instruction, and massed and distributed practice in emotional discrimination tasks. The experimental group showed significant improvements with respect to the control group both in accuracy in judging dynamic cues related to basic emotions and in the ability to make emotional inferences to determine whether a person was being sarcastic, sincere, or deceptive.

Guercio et al.45 trained 3 patients (2 with TBI) in affect recognition through matching images of equivalent facial expressions. The cues used were photographs of faces with angry, sad, and happy expressions. Patients’ ability to label facial affect and to match expressions was evaluated before and after the training. The results show an improvement in patients’ facial affect recognition skills. One of the main methodological issues in this study is that the treatment phase used the same cues as the pre- and post-treatment assessments; this, combined with the small sample size, represents a limitation for extrapolating the results.

It should be noted that all studies analysed in this review were performed independently, despite some being conducted by the same authors.

Discussion

The aim of this study is to present a systematic review of the literature on the rehabilitation of SC in patients with TBI. The study has several objectives: to establish the amount of work published to date on this topic; to evaluate the methodological quality of the research; and to assess the level of evidence of the interventions used.

An initial overview shows that little research has been done on this subject. We only identified 10 studies meeting the inclusion criteria. Of these, 6 were RCTs,33,37–41 one was a PCT,42 and 3 were case studies.43–45

The methodological quality of RCTs33,37–41 and the PCT42 ranged from good to excellent. The case studies43–45 were not evaluated with the PEDro scale and thus were considered to have poor methodological quality. According to the system proposed by Sackett et al.,36 the levels of evidence were level 1a for the RCTs,33,37–41 level 2 for the PCT,42 and level 5 for the case studies.43–45 However, it should be noted that the methodological quality of the articles was evaluated with the PEDro scale only, and other factors potentially affecting quality (eg, sample size) were not taken into account. Therefore, the levels of evidence established require clarification.

Nine studies33,37–41,43–45 report positive or partially positive results after treatment. This suggests that it is possible to improve SC in patients with TBI through the application of specific techniques by properly trained professionals. The PCT42 was the only study that did not find significant differences between the experimental and control groups.

A more detailed evaluation of the analysis performed and the characteristics of participating patients raises the following questions: is the effect of treatment affected by the stage of progression of TBI? What is the optimal duration and intensity of treatment? Should treatments be applied in isolation or in combination?

Early onset of rehabilitation treatment has classically been considered a positive prognostic factor for patient recovery.51–53 León-Carrión and Machuca54 report that spontaneous recovery ceases 8 months post-trauma; from that time, practically no cognitive improvement is observed without rehabilitation treatment. Similarly, other studies have shown that specialised treatments may lead to significant improvements in the functions targeted, even when treatment is applied years after trauma.55 The authors of the latter study posit that specialised interventions affect brain plasticity and cause changes even after spontaneous recovery has ceased. However, other studies describe a plateau phase in recovery,56,57 or even a tendency toward functional worsening over time,58 independently of treatment.

In the light of the observations discussed above, any systematic review must analyse the role of progression time. In 9 of the 10 studies analysed in this review, interventions were applied to patients with progression times ranging from 2.5 to 24 years; despite the inclusion of chronic patients, all studies (except for the PCT by McDonald et al.42) report positive changes after treatment. These results support the hypothesis, also proposed by Machuca et al.,59 that specific treatment performed by properly trained professionals can lead to the recovery of cognitive functions (and therefore SC), even in chronic patients. Another noteworthy observation is the lack of studies analysing the benefits of SC rehabilitation in patients with subacute and post-acute TBI. The positive results described in chronic patients should be replicated in patients with shorter progression times. In the light of this hypothesis, there is a clear need to implement SC rehabilitation programmes early after trauma as part of any holistic neurorehabilitation treatment. This represents a new field of research, as no study to date has addressed SC rehabilitation in patients with subacute and post-acute TBI.

The literature includes several studies reporting a direct relationship between treatment intensity and cognitive improvement.60–65 According to León-Carrión et al.,61 patients with TBI must receive more than 300 hours’ intensive rehabilitation therapy in order to obtain favourable outcomes. Positive associations are also reported between post-treatment improvements and treatment duration. Sandhaug et al.66 observed that longer stays at rehabilitation units were associated with better functional status at discharge. This improvement with longer treatment durations is even observed in chronic patients. It is also reported that patients with more severe TBI require greater treatment intensity and duration, in order to obtain better outcomes. This is exemplified in the study by Ashley et al.,67 which included patients with TBI of over one year’s progression: patients with mild-to-moderate disability (Disability Rating Scale68) showed improvements after 90 days of rehabilitation, whereas those with severe disability needed at least 180 days of treatment to achieve similar outcomes.

The results discussed in the previous paragraph may be interpreted differently: patients with greater initial severity will spend the most time receiving high-intensity rehabilitation. As these patients will have a poorer cognitive status at treatment onset, they will also be those who show the greatest changes after prolonged, intensive treatment. Hart et al.69 analyse the differences in treatment duration and intensity between the healthcare systems of 2 countries with similar characteristics (Denmark and the United States of America). Contrary to expectations, no differences were observed between Danish patients (who received more rehabilitation during the first year post-trauma) and American patients (who received less treatment) after the groups were adjusted to account for initial TBI severity.

The articles reviewed here report disparate results, and no firm conclusions can be drawn. Treatment duration ranged from 2hours (4 experimental conditions of 30minutes’ duration each in a single session),45 for the least intense intervention, to 25hours (1 weekly session of 2.5hours over 10 weeks).41 The changes observed seem to present no clear correlation with treatment intensity. However, it should be noted that the only study not clearly demonstrating positive results used a very low-intensity treatment (a total of 3hours).42

Regarding the benefits of monotherapy or combined therapy, current clinical practice guidelines recommend integrated, holistic neuropsychological rehabilitation addressing cognitive and functional deficits in patients with moderate or severe TBI.64 Our results on this issue are unclear. They do not support a clear relationship between treatment effectiveness and the number of techniques used. We may only indicate that the study using the greatest number of techniques37 obtained clearly positive outcomes, whereas the 3 studies using monotherapy43–45 obtained partially positive results in 2 cases and positive results in just one. Incidentally, the 3 studies using monotherapy are the 3 case studies reviewed.

The reviews published on the rehabilitation of SC in patients with TBI19,70–72 do not evaluate the methodological quality or level of evidence of the interventions applied. These reviews aimed to describe the available studies and to reflect on the mainly positive results presented in our “Summary of results” section. However, one review does question the benefits of treatment due to the methodological characteristics of the studies.

Similarly, and as commented above, we should be very cautious when interpreting results about the level of evidence of the different studies. Many of them used small patient samples, resulting in reduced statistical power for hypothesis testing. With small samples, statistically significant results can only be detected for very large effect sizes. However, clinical experience shows that effect sizes for this type of intervention tend to be small. Therefore, the fact that the studies reviewed include small samples but mainly report positive outcomes may suggest the possibility of false positives in the results, with the actual level of evidence being lower than the proposed level. In addition to this, the fact that some studies analyse numerous outcome measures, or have multiple arms, considerably increases the need to be cautious in our interpretation of the results reported.

In summary, these studies’ level of evidence may have been exaggerated. One possible solution would be the use of some methodology accounting for these variables when establishing the level of evidence. We should therefore temper our optimism about the effects and levels of evidence reported. Similarly, these considerations should be taken into account when interpreting the assertions made above. In accordance with the issues addressed above, it would be appropriate to indicate that the studies analysed present correct methodological quality and acceptable levels of evidence.

However, a significant limitation of this review is the small number of studies addressing SC rehabilitation in patients with TBI. Given this situation, we are unable to offer a clear response to the issues raised throughout the discussion. Future studies should aim to establish guidelines for the application of rehabilitation therapies for SC in patients with TBI. However, we must also stress that this study mainly aimed to establish the “doses” used (intensity, frequency, duration) and patient characteristics, rather than focusing on what Whyte et al.73 describe as the “active ingredients” of the treatment: the techniques used (content) and the process by which they are applied.

The main international guidelines on systematic reviews (eg, the PRISMA guidelines46) recommend that they be registered on public databases (eg, PROSPERO74) in order to ensure the transparency and replicability of the study performed. Similarly, data should be extracted by 2 independent researchers. Our study meets neither of these criteria; this limitation should be taken into account in future reviews.

Finally, we should mention the limitations inherent to evidence-based practice in neurorehabilitation. Evidence gives general guidance on how to treat patients; therefore, while treatment of patients should follow the available evidence, therapists are responsible for deciding how to treat patients as individuals.

Conclusions

This systematic review demonstrates that few studies have addressed SC rehabilitation in patients with TBI, although the experimental studies analysed present correct methodological quality and an acceptable level of evidence, which suggests that the treatments administered are largely effective. Another issue that should be highlighted is the fact that the majority of rehabilitation strategies used improve SC following TBI, despite the inclusion of chronic patients in these studies.

Conflicts of interest

The authors have no conflicts of interest to declare.

Acknowledgements

We would like to thank Olga Araujo (Centre de Documentació Santi Beso Arnalot, Institut Guttmann) for her assistance in the literature search. We are also grateful to the reviewers for their comments, which undoubtedly improved the quality of the manuscript.

References

[1]

V. Gallese.

Intentional attunement: a neurophysiological perspective on social cognition and its disruption in autism.

Brain Res, 1079 (2006), pp. 15-24

http://dx.doi.org/10.1016/j.brainres.2006.01.054 | Medline

[2]

R. Adolphs.

Cognitive neuroscience of human social behaviour.

Nat Rev Neurosci, 4 (2003), pp. 165-178

http://dx.doi.org/10.1038/nrn1056 | Medline

[3]

I. Sánchez-Cubillo, J. Tirapu, D. Adrover.

Neuropsicología de la cognición social y la autoconciencia.

Neuropsicología del cortex prefrontal y funciones ejecutivas, edition: 1, pp. 353-390

[4]

D.L. Penn, L.J. Sanna, D.L. Roberts.

Social cognition in Schizophrenia: an overview.

Schizophrenia Bulletin, 34 (2008), pp. 408-411

http://dx.doi.org/10.1093/schbul/sbn014 | Medline

[5]

D. Premack, G. Woodruff.

Does the chimpanzee have a theory of mind?.

Behav Brain Sci, 4 (1978), pp. 512-526

[6]

S. Baron-Cohen, A.M. Leslie, U. Frith.

Does the autistic child have a “theory of mind”?.

Cognition, 21 (1985), pp. 37-46

http://dx.doi.org/10.1016/0010-0277(85)90022-8 | Medline

[7]

R. Adolphs.

The neurobiology of social cognition.

Current opinion in Neurobiology, 11 (2001), pp. 231-239

http://dx.doi.org/10.1016/s0959-4388(00)00202-6 | Medline

[8]

S. McDonald, C. Honan, M. Kelly, L. Byom, J. Rushby.

Disorders of social cognition and social behaviour following severe TBI.

Social and communication disorders following traumatic brain injury, 2nd ed., pp. 119-159

[9]

K.A. Pelphrey, J.P. Morris, G. McCarthy.

Grasping the intentions of others: the perceived intentionality of an action influences activity in the superior temporal sulcus during social perception.

J Cogn Neurosci., 16 (2004), pp. 1706-1716

http://dx.doi.org/10.1162/0898929042947900 | Medline

[10]

K.N. Ochsner.

The social-emotional processing stream: five core constructs and their translational potential for schizophrenia and beyond.

Biol Psychiatry, 64 (2008), pp. 48-61

http://dx.doi.org/10.1016/j.biopsych.2008.04.024 | Medline

[11]

C.J. Cattran, M. Oddy, R.L. Wood, J.F. Moir.

Post-injury personality in the prediction of outcome following severe acquired brain injury.

Brain Injury, 25 (2011), pp. 1035-1046

http://dx.doi.org/10.3109/02699052.2011.607787 | Medline

[12]

C.L. Cooper, L.H. Phillips, M. Johnston, B. Radlak, S. Hamilton, M.J. McLeod.

Links between emotion perception and social participation restriction following stroke.

Brain Injury, 28 (2013), pp. 122-126

http://dx.doi.org/10.3109/02699052.2013.848379 | Medline

[13]

B. Englund, A. Brun, L. Gustafson, U. Passant, D. Mann, D. Neary, et al.

Clinical and neuropathological criteria for frontotemporal dementia.

Journal of Neurology, Neurosurgery & Psychiatry, 57 (1994), pp. 416-418

http://dx.doi.org/10.1016/j.ncl.2022.03.017 | Medline

[14]

D. Neary, J.S. Snowden, L. Gustafson, U. Passant, D. Stuss, S.A. Black, et al.

Frontotemporal lobar degeneration a consensus on clinical diagnostic criteria.

Neurology, 51 (1998), pp. 1546-1554

http://dx.doi.org/10.1212/wnl.51.6.1546 | Medline

[15]

M. Brüne.

Emotion recognition,’ theory of mind,’ and social behavior in schizophrenia.

Psychiatry Res., 133 (2005), pp. 135-147

http://dx.doi.org/10.1016/j.psychres.2004.10.007 | Medline

[16]

Couture S.M., Penn D.L., Roberts DL. The functional significance of social cognition in schizophrenia: a review. 2006; 32 Suppl 1:S44-63. Epub 2006 Aug 17. DOI:10.1093/schbul/sbl029.

[17]

L. Knox, J. Douglas.

Long-term ability to interpret facial expression after traumatic brain injury and its relation to social integration.

Brain & Cognition, 69 (2009), pp. 442-449

[18]

M. Milders, M. Ietswaart, J.R. Crawford, D. Currie.

Social behavior following traumatic brain injury and its association with emotion recognition, understanding of intentions, and cognitive flexibility.

Journal of the International Neuropsychological Society, 14 (2008), pp. 318-326

http://dx.doi.org/10.1017/S1355617708080351 | Medline

[19]

C. Bornhofen, S. McDonald.

Emotion perception deficits following traumatic brain injury: A review of the evidence and rationale for intervention.

Journal of the International Neuropsychological Society, 14 (2008), pp. 511-525

http://dx.doi.org/10.1017/S1355617708080703 | Medline

[20]

S. McDonald, J.C. Saunders.

Differential impairment in recognition of emotion across different media in people with severe traumatic brain injury.

Journal of the International Neuropsychological Society, 11 (2005), pp. 392-399

[21]

D.R. Babbage, J. Yim, B. Zupan, D. Neumann, M.R. Tomita, B. Willer.

Meta-analysis of facial affect recognition difficulties after traumatic brain injury.

Neuropsychology, 25 (2011), pp. 277-285

http://dx.doi.org/10.1037/a0021908 | Medline

[22]

B.L. Callahan, K. Ueda, D. Sakata, A. Plamondon, T. Murai.

Liberal bias mediates emotion recognition deficits in frontal traumatic brain injury.

Brain and Cognition, 77 (2011), pp. 412-418

http://dx.doi.org/10.1016/j.bandc.2011.08.017 | Medline

[23]

V. Croker, S. McDonald.

Recognition of emotion from facial expression following traumatic brain injury.

Brain Injury, 19 (2005), pp. 787-789

http://dx.doi.org/10.1080/02699050500110033 | Medline

[24]

A. Dimoska, S. McDonald, M.C. Pell, R.L. Tate, C.M. James.

Recognising vocal expressions of emotion following traumatic brain injury: Is the ‘what’ more important than the ‘how’?.

Journal of the International Neuropsychological Society, 16 (2010), pp. 369-382

http://dx.doi.org/10.1017/S1355617709991445 | Medline

[25]

J.F. Martín-Rodríguez, J. León-Carrión.

Theory of mind deficits in patients with adquired brain injury: a quantitative review.

Neuropsychologia, (2010), pp. 1181-1191

[26]

J. Grafman, A.M. Salazar.

The ebb and flow of traumatic brain injury research.

Handb Clin Neurol., 128 (2015), pp. 795-802

http://dx.doi.org/10.1016/B978-0-444-63521-1.00049-2 | Medline

[27]

S. McDonald.

Traumatic brain injury and psychosocial function: Let’s get social.

Brain Impairment, 4 (2003), pp. 36-47

[28]

J.L. Ponsford, M.G. Downing, J. Olver, M. Ponsford, R. Acher, M. Carty, et al.

Longitudinal follow-up of patients with traumatic brain injury: Outcome at two, five, and ten years post-injury.

Journal of Neurotrauma, 31 (2014), pp. 64-77

http://dx.doi.org/10.1089/neu.2013.2997 | Medline

[29]

F.M. Hammond, T. Hart, T. Bushnik, J.D. Corrigan, H. Sasser.

Change and predictors of change in communication, cognition, and social function between 1 and 5 years after traumatic brain injury.

Journal of Head Trauma Rehabilitation, 19 (2004), pp. 314-328

[30]

N. Frommann, M. Streit, W. Wolwer.

Remediation of facial affect recognition impairments in patients with schizophrenia: A new training program.

Psychiatry Research, 117 (2003), pp. 281-284

http://dx.doi.org/10.1016/s0165-1781(03)00039-8 | Medline

[31]

N. Bauminger.

The facilitation of social–emotional understanding and social interaction in high-functioning children with autism: Intervention outcomes.

Journal of Autism and Developmental Disorders, 32 (2002), pp. 283-298

http://dx.doi.org/10.1023/a:1016378718278 | Medline

[32]

K. McKenzie, E. Matheson, K. McKaskie, L. Hamilton, G.C. Murray.

Impact of group training on emotion recognition in individuals with a learning disability.

British Journal of Learning Disabilities, 28 (2000), pp. 143-147

[33]

C. Bornhofen, S. McDonald.

Treating deficits in emotion perception following traumatic brain injury.

Neuropsychological Rehabilitation, 18 (2008), pp. 22-24

http://dx.doi.org/10.1080/09602010601061213 | Medline

[34]

PEDro. Physiotherapy evidence database. https://www.pedro.org.au/spanish/downloads/pedro-scale/ [accessed 17.04.2018].

[35]

ERABI. Evidence-Based Review of Moderate to Severe Acquired Brain Injury (v-11; 2017). https://www.abiebr.com/pdf/executiveSummary.pdf [accessed 13.06.2018].

[36]

D. Sackett, S. Straus, W. Richardson, W. Rosenberg, R. Haynes.

Evidence-Based Medicine: How to Practice and Teach EBM.

CAN: Churchill Livingstone, (2000),

[37]

H.J. Westerhof-Evers, A.C. Visser-Keizer, L. Fasotti, M.C. Schönherr, M. Vink, J. van der Naalt, et al.

Effectiveness of a Treatment for Impairments in Social Cognition and Emotion Regulation (T-ScEmo) After Traumatic Brain Injury: A Randomized Controlled Trial.

J Head Trauma Rehabil., 32 (2017), pp. 296-307

http://dx.doi.org/10.1097/HTR.0000000000000332 | Medline

[38]

D. Neumann, D.R. Babbage, B. Zupan, B. Willer.

A randomized controlled trial of emotion recognition training after traumatic brain injury.

J Head Trauma Rehabil., 30 (2015),

[39]

S. McDonald, L. Togher, R. Tate, R. Randall, T. English, A. Gowland.

A randomised controlled trial evaluating a brief intervention for deficits in recognising emotional prosody following severe ABI.

Neuropsychological Rehabilitation, 23 (2013), pp. 267-286

http://dx.doi.org/10.1080/09602011.2012.751340 | Medline

[40]

D. Radice-Neumann, B. Zupan, M. Tomita, B. Willer.

Training Emotional Processing in Persons With Brain Injury.

JHeadTraumaRehabil, 24 (2009), pp. 313-323

[41]

C. Bornhofen, S. McDonald.

Comparing Strategies for Treating Emotion Perception Deﬁcits in Traumatic Brain Injury.

JHeadTraumaRehabil, 23 (2008), pp. 103-115

[42]

S. McDonald, C. Bornhofen, C. Hunt.

Addressing deficits in emotion recognition after severe traumatic brain injury: The role of focused attention and mimicry.

Neuropsychological Rehabilitation, 19 (2009), pp. 321-339

http://dx.doi.org/10.1080/09602010802193989 | Medline

[43]

J. Winegardner, C. Keohane, L. Prince, D. Neumann.

Perspective training to treat anger problems after brain injury: Two case studies.

NeuroRehabilitation, 39 (2016), pp. 153-162

http://dx.doi.org/10.3233/NRE-161347

[44]

J. Williamson, E. Isaki.

Facial Affect Recognition Training Through Telepractice: Two Case Studies of Individuals with Chronic Traumatic Brain Injury.

Int J Telerehabil., 7 (2015), pp. 13-20

http://dx.doi.org/10.5195/IJT.2015.6167 | Medline

[45]

J.M. Guercio, H. Podolska-Schroeder, R.A. Rehfeldt.

Using stimulus equivalence technology to teach emotion recognition to adults with acquired brain injury.

Brain Injury, 18 (2004), pp. 593-601

http://dx.doi.org/10.1080/02699050310001646116 | Medline

[46]

D. Moher, A. Liberati, J. Tetzlaff, D.G. Altman, PRISMA Group.

Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement.

PLoS Med., 6 (2009),

[47]

F.B. Bryant, B.D. Smith.

Refining the architecture of aggression: A measurement model for the Buss–Perry Aggression Questionnaire.

Journal of Research in Personality, 35 (2001), pp. 138-167

http://dx.doi.org/10.1006/jrpe.2000.2302

[48]

M.H. Davis.

A multidimensional approach to individual differences in empathy.

Catalog of Selected Documents in Psycholog, 10 (1980), pp. 1-17

[49]

P. Ekman.

Expression and the nature of emotion.

Approaches to emotion, pp. 319-344

[50]

D.L. Penn, D. Combs.

Modiﬁcation of affect perception deﬁcits in schizophrenia.

Schizophrenia Research, 46 (2000), pp. 217-229

http://dx.doi.org/10.1016/s0920-9964(00)00005-0 | Medline

[51]

D.S. Gray, R.S. Burnham.

Preliminary outcome analysis of a long-term rehabilitation program for severe acquired brain injury.

Arch Phys Med Rehabil, 81 (2000), pp. 1447-1456

http://dx.doi.org/10.1053/apmr.2000.16343 | Medline

[52]

S.D. Horn, G. DeJong, R.J. Smout, J. Gassaway, R. James, B. Conroy.

Stroke rehabilitation patients, practice, and outcomes: is earlier and more aggressive therapy better?.

Arch Phys Med Rehabil, 86 (2005), pp. S101-14

http://dx.doi.org/10.1016/j.apmr.2005.09.016 | Medline

[53]

B. Kolb, G.C. Teskey, R. Gibb.

Factors influencing cerebral plasticity in the normal and injured brain.

Frontiers in Human Neuroscience, 4 (2010),

[54]

J. León-Carrión, F. Machuca.

Spontaneous recovery of cognitive functions after traumatic brain injury: When are neurocognitive sequelae established?.

Revista Española de Neuropsicología, 3 (2001), pp. 58-67

[55]

F. Machuca, J. León-Carrión, R. Dominguez-Morales, J.M. Barroso y Martin.

Do holistic, intensive and multidisciplinary rehabilitation programs improve the functional independency in severe traumatic brain injury patients? A preliminary study using the FIM+FAM.

Brain Injury, 17 (2003), pp. 91-92

[56]

L. Ruttan, K. Martin, A. Liu, B. Colella, R.E. Green.

Long-term cognitive outcome in moderate to severe traumatic brain injury: a meta-analysis examining timed and untimed tests at 1 and 4.5 or more years after injury.

Arch Phys Med Rehabil., 89 (2008),

[57]

J. Livingston-Thomas, P. Nelson, S. Karthikeyan, S. Antonescu, M.S. Jeffers, S. Marzolini, et al.

Exercise and Environmental Enrichment as Enablers of Task-Specific Neuroplasticity and Stroke Recovery.

Neurotherapeutics, 13 (2016), pp. 395-402

http://dx.doi.org/10.1007/s13311-016-0423-9

[58]

B.E. Masel, D.S. DeWitt.

Traumatic brain injury: a disease process, not an event.

Journal of Neurotrauma, 27 (2010), pp. 1529-1540

http://dx.doi.org/10.1089/neu.2010.1358 | Medline

[59]

F. Machuca, J. León-Carrión, J.M. Barroso y Martin.

Eficacia de la rehabilitación neuropsicológica de origen tardío en la recuperación funcional de pacientes con daño cerebral traumático.

Revista Española de Neuropsicología, 8 (2006), pp. 81-103

[60]

Rt Seel, Jd Corrigan, Mp Dijkers, Rs Barrett, J. Bogner, Rj Smout, et al.

Patient Effort in Traumatic Brain Injury Inpatient Rehabilitation: Course and Associations With Age, Brain Injury Severity, and Time Postinjury.

Arch Phys Med Rehabil, 96 (2015), pp. S235-S244

http://dx.doi.org/10.1016/j.apmr.2014.10.027 | Medline

[61]

J. León-Carrión, M.R. Domínguez-Morales, J.M. Barroso y Martín, U. Leon-Dominguez.

Recovery of cognitive function during comprehensive rehabilitation after severe traumatic brain injury.

J Rehabil Med., 44 (2012), pp. 505-511

http://dx.doi.org/10.2340/16501977-0982

[62]

J. León-Carrión, F. Machuca-Murga, I. Solís-Marcos, U. León-Domínguez, M.R. Domínguez-Morales.

The sooner patients begin neurorehabilitation, the better their functional outcome.

Brain Inj., 27 (2013), pp. 1119-1123

http://dx.doi.org/10.3109/02699052.2013.804204 | Medline

[63]

K.D. Cicerone, T. Mott, J. Azulay, J.C. Friel.

Community integration and satisfaction with functioning after intensive cognitive rehabilitation for traumatic brain injury.

Arch Phys Med Rehabil, 85 (2004), pp. 943-950

http://dx.doi.org/10.1016/j.apmr.2003.07.019 | Medline

[64]

K.D. Cicerone, D.M. Langenbahn, C. Braden, J.F. Malec, K. Kalmar, M. Fraas, et al.

Evidence-based cognitive rehabilitation: updated review of the literature from 2003 through 2008.

Archives of Physical Medicine and Rehabilitation., 92 (2011), pp. 519-530

http://dx.doi.org/10.1016/j.apmr.2010.11.015 | Medline

[65]

M.L. Rohling, M.E. Faust, B. Beverly, G. Demakis.

Effectiveness of cognitive rehabilitation following acquired brain injury: a meta-analytic re-examination of Cicerone et al.’s (2000, 2005) systematic reviews.

Neuropsychology., 23 (2009), pp. 20-39

http://dx.doi.org/10.1037/a0013659

[66]

M. Sandhaug, N. Andelic, A. Vatne, S. Seiler, A. Mygland.

Functional level during sub-acute rehabilitation after traumatic brain injury: course and predictors of outcome.

Brain Inj., 24 (2010), pp. 740-747

http://dx.doi.org/10.3109/02699051003652849 | Medline

[67]

J.G. Ashley, M.J. Ashley, B.E. Masel, K. Randle, L.A. Kreber, C. Singh, et al.

The influence of post-acute rehabilitation length of stay on traumatic brain injury outcome: a retrospective exploratory study.

Brain Injury, (2018),

http://dx.doi.org/10.1080/02699052.2018.1432896 | Medline

[68]

M. Rappaport, K.M. Hall, K. Hopkins, T. Belleza, N. Cope.

Disability Rating Scale for severe head trauma: coma to community.

Arch Phys Med Rehabil., 63 (1982), pp. 118-123

Medline

[69]

T. Hart, J. Whyte, I. Poulsen, K.S. Kristensen, A.M. Nordenbo, I. Chervoneva, et al.

How Do Intensity and Duration of Rehabilitation Services Affect Outcomes From Severe Traumatic Brain Injury? A Natural Experiment Comparing Health Care Delivery Systems in 2 Developed Nations.

Arch Phys Med Rehabil., 97 (2016), pp. 2045-2053

http://dx.doi.org/10.1016/j.apmr.2016.07.012

[70]

A. Cassel, S. McDonald, M. Kelly, L. Togher.

Learning from the minds of others: A review of social cognition treatments and their relevance to traumatic brain injury.

Neuropsychol Rehabil., 30 (2016), pp. 1-34

http://dx.doi.org/10.1080/09602011.2016.1257435 | Medline

[71]

D.M. Driscoll, O. Dal Monte, J. Grafman.

A need for improved training interventions for the remediation of impairments in social functioning following brain injury.

J Neurotrauma., 28 (2011), pp. 319-326

http://dx.doi.org/10.1089/neu.2010 | Medline

[72]

T. Manly, F.C. Murphy.

Rehabilitation of executive function and social cognition impairments after brain injury.

Curr Opin Neurol., 25 (2012), pp. 656-661

http://dx.doi.org/10.1097/WCO.0b013e3283594872 | Medline

[73]

J. Whyte, M.P. Dijkers, T. Hart, J.M. Zanca, A. Packel, M. Ferraro, et al.

Development of a theory-driven rehabilitation treatment taxonomy: conceptual issues.

Arch Phys Med Rehabil, 95 (2014), pp. S24-32

[74]

PROSPERO. International prospective register of systematic reviews. http://www.crd.york.ac.uk/prospero/ [accessed 14.06.2018].

☆

Please cite this article as: Rodríguez-Rajo P, Leno Colorado D, Enseñat-Cantallops A, García-Molina A. Rehabilitación de la cognición social en el traumatismo craneoencefálico: una revisión sistemática. Neurología. 2022;37:767–780.

Indexada en:

Síguenos:

Indexada en:

Síguenos:

Suscríbase a la newsletter