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The contribution of virtual reality to cognitive intervention for individuals with neurodegenerative disease or at risk Volume 14, issue 2, Avril-Mai-Juin 2022

  • [1.] Weech S, Kenny S, Barnett-Cowan M. Presence and cybersickness in virtual reality are negatively related: A review. Front Psychol 2019; 10: 158.
  • [2.] Plancher G, Nicolas S, Piolino P. Apport de la réalité virtuelle en neuropsychologie de la mémoire : étude dans le vieillissement. Psychol Neuropsychiatr Vieil 2008 ; 6 : 7-22.
  • [3.] Shuchat J, Ouellet É, Moffat N, et al. Opportunities for virtual reality in cognitive training with persons with mild cognitive impairment or Alzheimer’s disease. Non-Pharmacological Therapies in Dementia 2012; 3: 35-54.
  • [4.] Abichou K, La Corte V, Piolino P. Does virtual reality have a future for the study of episodic memory in aging? Geriatr Psychol Neuropsychiatr Vieil 2017; 15: 65-74.
  • [5.] La Corte V, Sperduti M, Abichou K, et al. Episodic memory assessment and remediation in normal and pathological aging using virtual reality: A mini review. Front Psychol 2019; 10: 173.
  • [6.] Plancher G, Gyselinck V, Nicolas S, et al. Age effect on components of episodic memory and feature binding: A virtual reality study. Neuropsychology 2010; 24: 379-90.
  • [7.] Jebara N, Orriols E, Zaoui M, et al. Effects of enactment in episodic memory: a pilot virtual reality study with young and elderly adults. Front Aging Neurosci 2014; 6: 338.
  • [8.] Cushman LA, Stein K, Duffy CJ. Detecting navigational deficits in cognitive aging and Alzheimer disease using virtual reality. Neurology 2008; 71: 888-95.
  • [9.] Allain P, Foloppe DA, Besnard J, et al. Detecting everyday action deficits in Alzheimer’s disease using a nonimmersive virtual reality kitchen. J Int Neuropsychol Soc 2014; 20: 468-77.
  • [10.] Corriveau Lecavalier N, Ouellet É, Boller B, et al. Use of immersive virtual reality to assess episodic memory: A validation study in older adults. Neuropsychol Rehabil 2020; 30: 462-80.
  • [11.] Ouellet É, Boller B, Corriveau-Lecavalier N, et al. The Virtual Shop: A new immersive virtual reality environment and scenario for the assessment of everyday memory. J Neurosci Methods 2018; 303: 126-35.
  • [12.] Hofmann M, Rösler A, Schwarz W, et al. Interactive computertraining as a therapeutic tool in Alzheimer’s disease. Compr Psychiatry 2003; 44: 213-9.
  • [13.] Man DW, Chung JC, Lee GY. Evaluation of a virtual reality-based memory training programme for Hong Kong Chinese older adults with questionable dementia: a pilot study. Int J Geriatr Psychiatry 2012; 27: 513-20.
  • [14.] Boller B, Prieto del Val L, Belleville S. Cognitive training in mild cognitive impairment. In: Strobach T, Karbach J (eds). Cognitive training: an overview of features and applications. Cham: Springer International Publishing, 2021. p. 381-93.
  • [15.] Optale G, Urgesi C, Busato V, et al. Controlling memory impairment in elderly adults using virtual reality memory training: a randomized controlled pilot study. Neurorehabil Neural Repair 2010; 24: 348-57.
  • [16.] Manera V, Chapoulie E, Bourgeois J, et al. A feasibility study with image-based rendered virtual reality in patients with mild cognitive impairment and dementia. PLoS One 2016; 11: e0151487.
  • [17.] White PJ, Moussavi Z. Neurocognitive treatment for a patient with Alzheimer’s disease using a virtual reality navigational environment. J Exp Neurosci 2016; 10: 129-35.
  • [18.] Serino S, Pedroli E, Tuena C, et al. A novel rirtual reality-based training protocol for the enhancement of the «Mental Frame Syncing» in individuals with Alzheimer’s disease: A development-of-concept trial. Front Aging Neurosci 2017; 9: 240.
  • [19.] Maggio MG, De Cola MC, Latella D, et al. What about the role of virtual reality in Parkinson disease’s cognitive rehabilitation? Preliminary findings from a randomized clinical trial. J Geriatr Psychiatry Neurol 2018; 31: 312-8.
  • [20.] Maggio MG, De Luca R, Manuli A, et al. Do patients with multiple sclerosis benefit from semi-immersive virtual reality? A randomized clinical trial on cognitive and motor outcomes. Appl Neuropsychol Adult 2022; 29: 59-65.
  • [21.] Kim H, Hong JP, Kang JM, et al. Cognitive reserve and the effects of virtual reality-based cognitive training on elderly individuals with mild cognitive impairment and normal cognition. Psychogeriatrics 2021; 21: 552-9.
  • [22.] Boller B, Belleville S. Capacités de réserve et entraînement cognitif dans le vieillissement : similarité des effets protecteurs sur la cognition et le cerveau. Rev Neuropsychol 2016 ; 8 : 245-52.
  • [23.] Belleville S, Mellah S, de Boysson C, et al. The pattern and loci of training-induced brain changes in healthy older adults are predicted by the nature of the intervention. PLoS One 2014; 9: e102710.
  • [24.] Ansado J, Brulé J, Chasen C, et al. The virtual reality workingmemory-training program (VR WORK M): Description of an individualized, integrated program. Annu Rev CyberTherapy Telemed 2018; 16: 101-8.
  • [25.] Boller B, Ansado J, Bouchard S, et al. Using virtual reality to assess and train working memory in older adults. In préparation.
  • [26.] Bier B, Ouellet E, Belleville S. Computerized attentional training and transfer with virtual reality: Effect of age and training type. Neuropsychology 2018; 32: 597-614.
  • [27.] Boller B, Ouellet É, Belleville S. Using virtual reality to assess and promote transfer of memory training in older adults with memory complaints: A randomized controlled trial. Front Psychol 2021; 12: 627242.
  • [28.] Yip BC, Man DW. Virtual reality-based prospective memory training program for people with acquired brain injury. NeuroRehabilitation 2013; 32: 103-15.
  • [29.] Boujut A, Mellah S, Lussier M, et al. Assessing the effect of training on the cognition and brain of older adults: Protocol for a three-arm randomized double-blind controlled trial (ACTOP). JMIR Res Protoc 2020; 9: e20430.
  • [30.] Boujut A, Verty LV, Maltezos S, et al. Effects of computerized updating and inhibition training in older adults: The ACTOP three-arm randomized double-blind controlled Trial. Front Neurol [Clinical Trial]. 2020; 11.
  • [31.] Boujut A, Belleville S. Où en est-on avec les programmes d’interventions cognitives pour les personnes âgées ? Rev Neuropsychol 2019; 11 : 60-69.
  • [32.] Belleville S, Hudon C, Bier N, et al. MEMO+: Efficacy, durability and effect of cognitive training and psychosocial intervention in individuals with mild cognitive impairment. J Am Geriatr Soc 2018; 66: 655-63.
  • [33.] Boujut A, Lemieux V, Belleville S, et al. The benefit of immersive virtual reality for cognitive training in older adults. In preparation.
  • [34.] Bauer ACM, Andringa G. The potential of immersive virtual reality for cognitive training in elderly. Gerontology 2020; 66: 614-23.
  • [35.] Belleville S, Boller B. Comprendre le stade compensatoire de la maladie d’Alzheimer et agir pour promouvoir la cognition et la plasticite cerebrale. Can J Exp Psychol 2016 ; 70 : 288-94.
  • [36.] Belleville S, Clément F, Mellah S et al. Training-related brain plasticity in subjects at risk of developing Alzheimer’s disease. Brain 2011; 134: 1623-34.
  • [37.] Ansado J, Chasen C, Bouchard S, et al. How brain imaging provides predictive biomarkers for therapeutic success in the context of virtual reality cognitive training. Neurosci Biobehav Rev 2021; 120: 583-94.