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Artykuły w czasopismach na temat „Neuroplasticity”

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Autor: Grafiati
Data publikacji: 4 czerwca 2021
Data aktualizacji: 30 lipca 2024

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1

Németh, Viktor. "Neuroplasticity". Belügyi Szemle 69, nr 6. ksz. (1.12.2021): 124–27. http://dx.doi.org/10.38146/bsz.spec.2021.6.8.

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As editor Bruce Tidor sets it in the preface of the book, published in the volume of the MIT Essential Knowledge series: ‘Synthesizing specialized subject matter for non-specialists and engaging critical topics through fundamentals, each of these compact volumes offers readers a point of access to complex ideas.’ (Costandi, 2016). In this book of the series Moheb Costandi provides the reader with a celar and coherent picture about neuroplasticity and neurogenesis . Not just at the level of theories and research results, but also regarding various stages of practical application. It is equally applicable for average people in areas of everyday life- adult education, lifelong learning, and mental training, too. Costandi’s book is decidedly good background material for Anders Hansen’s practical book ‘The Real Happy Pill: Power Up Your Brain by Moving Your Body’ (Németh, 2020).
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Thompson, Cynthia K. "Neuroplasticity". Journal of Communication Disorders 33, nr 4 (lipiec 2000): 357–66. http://dx.doi.org/10.1016/s0021-9924(00)00031-9.

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Spitzer, M. "Neuroplasticity". European Psychiatry 17 (maj 2002): 12. http://dx.doi.org/10.1016/s0924-9338(02)80053-0.

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de Oliveira, Rúbia Maria Weffort. "Neuroplasticity". Journal of Chemical Neuroanatomy 108 (październik 2020): 101822. http://dx.doi.org/10.1016/j.jchemneu.2020.101822.

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Lenn, Nicholas J. "Neuroplasticity". Infants & Young Children 3, nr 3 (styczeń 1991): 39–48. http://dx.doi.org/10.1097/00001163-199101000-00007.

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Damulin, I. V. Damulin. "MALADAPTIVE NEUROPLASTICITY". Pharmateca 10_2018 (19.10.2018): 6–10. http://dx.doi.org/10.18565/pharmateca.2018.10.6-10.

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Lawtoo, Nidesh. "Conrad’s Neuroplasticity". Modernism/modernity 23, nr 4 (2016): 771–88. http://dx.doi.org/10.1353/mod.2016.0073.

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8

Naryshkin, A. G., I. V. Galanin i A. Yu Egorov. "Controlled Neuroplasticity". Human Physiology 46, nr 2 (marzec 2020): 216–23. http://dx.doi.org/10.1134/s0362119720020103.

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9

Larsen, Deborah S. "Why Neuroplasticity?" Journal of Neurologic Physical Therapy 36, nr 2 (czerwiec 2012): 110–11. http://dx.doi.org/10.1097/npt.0b013e3182567076.

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10

Morley, J. S. "Central neuroplasticity". Pain 54, nr 3 (wrzesień 1993): 363–64. http://dx.doi.org/10.1016/0304-3959(93)90042-n.

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Vinogradov, Sophia. "Harnessing neuroplasticity". Psychiatry Research 330 (grudzień 2023): 115607. http://dx.doi.org/10.1016/j.psychres.2023.115607.

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12

Gynther, Bruce D., Mike B. Calford i Pankaj Sah. "Neuroplasticity and Psychiatry". Australian & New Zealand Journal of Psychiatry 32, nr 1 (luty 1998): 119–28. http://dx.doi.org/10.3109/00048679809062718.

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Objective: There is increasing concern that the course of psychiatric disorders may be affected by parameters such as the duration and intensity of symptoms of initial episodes of illness. As this indicates that abnormal function produces long-term changes within the brain, a review of the neuroscience literature regarding neuroplasticity is warranted. Method: This article is a selective review, focusing in particular on results obtained from physiological experiments assessing plasticity within the mammalian neocortex. The possible relevance of results to psychiatry is discussed. Results: While the most dramatic examples of neuroplasticity occur during a critical period of neural development, neuroplasticity can also occur in adult neocortex. Neuroplasticity appears to be activity-dependent: synaptic pathways that are intensively used may become strengthened, and conversely, there may be depression of transmission in infrequently used pathways. Conclusions: Results from neurophysiological experiments lend support to the clinical observation that the intensity and duration of a psychiatric disorder may adversely alter its long-term course. Rapid aggressive treatment may prevent this from occurring. While pharmacotherapy may reduce the duration and severity of symptoms, it may also have an independent, as yet unknown, effect on neuroplasticity.
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13

Poluektov, M. G. "Sleep and neuroplasticity". Zhurnal nevrologii i psikhiatrii im. S.S. Korsakova 119, nr 4 (2019): 7. http://dx.doi.org/10.17116/jnevro20191190427.

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Cheng, Aiwu, Yan Hou i Mark P. Mattson. "Mitochondria and Neuroplasticity". ASN Neuro 2, nr 5 (2.09.2010): AN20100019. http://dx.doi.org/10.1042/an20100019.

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15

Greene, Charles S. "Neuroplasticity and Sensitization". Journal of the American Dental Association 140, nr 6 (czerwiec 2009): 676–78. http://dx.doi.org/10.14219/jada.archive.2009.0253.

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Beganović, Ana, i Jerko Anđelić. "Neuroplasticity in artists". Gyrus 3, nr 1 (2015): 14–16. http://dx.doi.org/10.17486/gyr.3.1004.

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Zolyniak, Nicole, Heike Schulte-Göcking i Eduard Kraft. "Neuroplasticity in Aging". Topics in Geriatric Rehabilitation 30, nr 1 (2014): 15–17. http://dx.doi.org/10.1097/tgr.0000000000000004.

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18

Jones, Edward G. "Plasticity and Neuroplasticity". Journal of the History of the Neurosciences 13, nr 3 (wrzesień 2004): 293. http://dx.doi.org/10.1080/09647040490510597.

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19

Sator-Katzenschlager, Sabine. "Pain and neuroplasticity". Revista Médica Clínica Las Condes 25, nr 4 (lipiec 2014): 699–706. http://dx.doi.org/10.1016/s0716-8640(14)70091-4.

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20

Tailor, Vijay K., D. Samuel Schwarzkopf i Annegret H. Dahlmann-Noor. "Neuroplasticity and amblyopia". Current Opinion in Neurology 30, nr 1 (luty 2017): 74–83. http://dx.doi.org/10.1097/wco.0000000000000413.

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21

Grafman, Jordan. "Conceptualizing functional neuroplasticity". Journal of Communication Disorders 33, nr 4 (lipiec 2000): 345–56. http://dx.doi.org/10.1016/s0021-9924(00)00030-7.

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22

Khan, Fary, Bhasker Amatya, Mary P. Galea, Roman Gonzenbach i Jürg Kesselring. "Neurorehabilitation: applied neuroplasticity". Journal of Neurology 264, nr 3 (24.10.2016): 603–15. http://dx.doi.org/10.1007/s00415-016-8307-9.

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23

Damulin, I. V., i E. V. Ekusheva. "Stroke and neuroplasticity". Zhurnal nevrologii i psikhiatrii im. S.S. Korsakova 114, nr 12 (2014): 136. http://dx.doi.org/10.17116/jnevro2014114121136-142.

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24

Damulin, I. V., i E. V. Ekusheva. "Poststroke neuroplasticity processes". Neurology, Neuropsychiatry, Psychosomatics, nr 3 (23.10.2014): 69. http://dx.doi.org/10.14412/2074-2711-2014-3-69-74.

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25

Castro-Couch, M., i T. F. Bergquist. "Neuroplasticity and Rehabilitation". Archives of Clinical Neuropsychology 27, nr 4 (12.04.2012): 466–67. http://dx.doi.org/10.1093/arclin/acs040.

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26

Finger, Stanley. "Neuroplasticity and Development". Contemporary Psychology: A Journal of Reviews 34, nr 12 (grudzień 1989): 1082–83. http://dx.doi.org/10.1037/030805.

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27

D'Sa, Carrol, i Ronald S. Duman. "Antidepressants and neuroplasticity". Bipolar Disorders 4, nr 3 (czerwiec 2002): 183–94. http://dx.doi.org/10.1034/j.1399-5618.2002.01203.x.

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28

Frost, Douglas O., Carol A. Tamminga, Deborah R. Medoff, Verne Caviness, Georgio Innocenti i William T. Carpenter. "Neuroplasticity and schizophrenia". Biological Psychiatry 56, nr 8 (październik 2004): 540–43. http://dx.doi.org/10.1016/j.biopsych.2004.01.020.

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29

Martin, Ruth E. "Neuroplasticity and Swallowing". Dysphagia 24, nr 2 (7.01.2009): 218–29. http://dx.doi.org/10.1007/s00455-008-9193-9.

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30

Mundkur, Nandini. "Neuroplasticity in children". Indian Journal of Pediatrics 72, nr 10 (październik 2005): 855–57. http://dx.doi.org/10.1007/bf02731115.

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31

Mateer, Catherine A., i Kimberly A. Kerns. "Capitalizing on Neuroplasticity". Brain and Cognition 42, nr 1 (luty 2000): 106–9. http://dx.doi.org/10.1006/brcg.1999.1175.

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32

Spytska, Liana. "The Impact of Physical Activity on Brain Neuroplasticity, Cognitive Functions and Motor Skills". OBM Neurobiology 08, nr 02 (25.04.2024): 1–10. http://dx.doi.org/10.21926/obm.neurobiol.2402219.

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The research aims to study the mechanisms and factors contributing to brain neuroplasticity. To achieve this goal, the following methods were used: analysis and synthesis, hermeneutic method, psychological testing, and comparative and generalization methods. The research results revealed the nature of the concept of brain neuroplasticity and types of neuroplasticity, analyzed the process of redistribution of brain functions, determined the role of compensatory plasticity, revealed methods of studying brain neuroplasticity, investigated the influence of brain processes on the course of learning, memory development, awareness, concentration, speech; identified factors that can affect brain neuroplasticity revealed the role of genetic factors, analyzed stimulation and rehabilitation methods to promote neuroplasticity. The findings may aid in developing novel rehabilitation techniques, specifically for stroke patients, by utilizing the brain’s compensatory abilities through physical activity, pharmacological interventions, and stimulation techniques. The practical significance of the research is determined by the current disclosure of the features of brain neuroplasticity to understand its ability to reorganize the sensory and perceptual systems.
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33

Kennedy, Niamh C. "The role of neuroplasticity in stroke nursing". British Journal of Neuroscience Nursing 17, Sup2 (1.04.2021): S20—S25. http://dx.doi.org/10.12968/bjnn.2021.17.sup2.s20.

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Background: Neuroplasticity refers to the brain's ability to reorganise and change in response to experience or after brain damage. Neuroplasticity is an imperative component of recovery from stroke, and rehabilitation aims to capitalise on this during a patient's recovery. Aims: To highlight the role of neuroplasticity in stroke recovery and to explore how stroke nursing can use it. Methods: The paper is a narrative review of the literature on neuroplasticity and role of nursing in stroke recovery. Findings: Nurses can play a pivotal role in ensuring optimum conditions for neuroplasticity through a variety of means. These include the encouragement of repetition, integration of repetition into everyday tasks, creating a stimulating environment, educating stroke patients as well as their carers about the recovery process and working as part of multidisciplinary team. Conclusions: This paper highlights the important role stroke nursing can play in enhancing neuroplasticity during stroke recovery.
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34

Maritska, Ziske, Muhammad Fakhri Altyan, Ardy Oktaviandi, Muhammad Barkah, Amirah Dhia Nabila Sinum, Emelda Emelda, Hawari Martanusa i in. "Genetic Factors Affecting Neuroplasticity". Sriwijaya Journal of Medicine 6, nr 2 (15.07.2023): 39–47. http://dx.doi.org/10.32539/sjm.v6i2.152.

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Neuroplasticity pertains to the brain's ability to adjust functions or structure in response to events and is an important factor for skill-learning development as well as functional recovery from a neurological disorder. Numerous factors could influence neuroplasticity processes. This literature review aims to discuss the roles of genetic factors in neuroplasticity. The literature search was conducted using the keywords “neuroplasticity”, genetics”, “genes”, and polymorphism” in search engines like google scholar and PubMed, covering original articles, reviews, and text book both in Bahasa Indonesia and English for the last ten years. Genetic variation including gene polymorphism was responsible for the impact of BDNF, ApoE, and dopamine on the functional neural repair of the brain. Certain processes might directly influence neuroplasticity; others might interfere indirectly through the process. A deeper insight into genetic influence regarding neuroplasticity could lead to a better understanding and potential improvement of treatment.
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35

Kadykov, A. S., N. V. Shakhparonova, A. V. Belopasova i J. V. Prjanikov. "A NEUROPLASTICITY AND FUNCTIONAL RESTORATION AFTER STROKE". Physical and rehabilitation medicine, medical rehabilitation 1, nr 2 (15.06.2019): 32–36. http://dx.doi.org/10.36425/2658-6843-19184.

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The article discusses the history of brain neuroplasticity, its effect on the restoration of functions after a stroke. Various mechanisms of neuroplasticity are considered: functions of reorganization, neurogenesis, the effect on neuroplasticity of training, the use of various rehabilitation techniques, and drug therapy.
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36

Frizzell, Tory O., Elisha Phull, Mishaa Khan, Xiaowei Song, Lukas A. Grajauskas, Jodie Gawryluk i Ryan C. N. D’Arcy. "Imaging functional neuroplasticity in human white matter tracts". Brain Structure and Function 227, nr 1 (23.11.2021): 381–92. http://dx.doi.org/10.1007/s00429-021-02407-4.

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AbstractMagnetic resonance imaging (MRI) studies are sensitive to biological mechanisms of neuroplasticity in white matter (WM). In particular, diffusion tensor imaging (DTI) has been used to investigate structural changes. Historically, functional MRI (fMRI) neuroplasticity studies have been restricted to gray matter, as fMRI studies have only recently expanded to WM. The current study evaluated WM neuroplasticity pre–post motor training in healthy adults, focusing on motor learning in the non-dominant hand. Neuroplasticity changes were evaluated in two established WM regions-of-interest: the internal capsule and the corpus callosum. Behavioral improvements following training were greater for the non-dominant hand, which corresponded with MRI-based neuroplasticity changes in the internal capsule for DTI fractional anisotropy, fMRI hemodynamic response functions, and low-frequency oscillations (LFOs). In the corpus callosum, MRI-based neuroplasticity changes were detected in LFOs, DTI, and functional correlation tensors (FCT). Taken together, the LFO results converged as significant amplitude reductions, implicating a common underlying mechanism of optimized transmission through altered myelination. The structural and functional neuroplasticity findings open new avenues for direct WM investigations into mapping connectomes and advancing MRI clinical applications.
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Salma, Asem. "Hebbian Neuroplasticity versus Meta-neuroplasticity and the Relevance for Neurosurgical Innovation". World Neurosurgery 82, nr 5 (listopad 2014): e667-e668. http://dx.doi.org/10.1016/j.wneu.2014.06.052.

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Farzan Vahedifard i Atieh Sadeghniiat Haghighi. "The role of Neuroradiology in Neuroplasticity: New advancements". World Journal of Advanced Research and Reviews 14, nr 2 (30.05.2022): 156–60. http://dx.doi.org/10.30574/wjarr.2022.14.2.0420.

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Neuroplasticity, the brain’s capacity to adapt to internal and external environmental changes, occurs physiologically throughout growth and in reaction to damage. Many MRI studies of neuroplasticity have shown strong evidence that the brain changes quickly and extensively when people have new experiences. · In this paper, we review the most advancement in the role of neuroradiology in neuroplasticity and using biomarkers. o Detecting neuroplasticity in global brain circuits in vivo is critical for understanding various processes such as memory, learning, and injury healing. o MRI-biomarkers can be used to check for corticospinal integrity and how well motor resources are used. White matter neuroplasticity is studied via MRI. It has been used to study structural changes using diffusion tensor imaging (DTI) o The ultrafast fMRI (ufMRI) technique allows for high spatiotemporal sensitivity and resolution in dispersed brain circuits to detect fMRI signals more connected with the underlying neural dynamics. White matter hemodynamics may change over time, explaining functional neuroplasticity in this tissue.
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Abuleil, Dania, Benjamin Thompson i Kristine Dalton. "Aerobic Exercise and Human Visual Cortex Neuroplasticity: A Narrative Review". Neural Plasticity 2022 (23.07.2022): 1–9. http://dx.doi.org/10.1155/2022/6771999.

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There is compelling evidence from animal models that physical exercise can enhance visual cortex neuroplasticity. In this narrative review, we explored whether exercise has the same effect in humans. We found that while some studies report evidence consistent with exercise-induced enhancement of human visual cortex neuroplasticity, others report no effect or even reduced neuroplasticity following exercise. Differences in study methodology may partially explain these varying results. Because the prospect of exercise increasing human visual cortex neuroplasticity has important implications for vision rehabilitation, additional research is required to resolve this discrepancy in the literature.
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40

Singh, Shailendra. "Neuroplasticity and Rehabilitation: Harnessing Brain Plasticity for Stroke Recovery and Functional Improvement". Universal Research Reports 11, nr 3 (30.06.2024): 50–56. http://dx.doi.org/10.36676/urr.v11.i3.1287.

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This paper provides a comprehensive review of the current understanding of neuroplasticity and its application in stroke rehabilitation. Stroke remains a leading cause of disability worldwide, often resulting in motor, sensory, and cognitive impairments. Neuroplasticity, the brain's ability to reorganize and adapt in response to experience and injury, offers promising avenues for recovery. This review discusses key principles of neuroplasticity and explores various rehabilitation strategies aimed at harnessing its potential for stroke recovery. Topics covered include early intervention, task-specific training, intensity and repetition, constraint-induced movement therapy, multimodal approaches, environmental enrichment, and neurostimulation techniques. Additionally, the paper discusses emerging research directions and challenges in optimizing neuroplasticity-based rehabilitation approaches. Understanding the role of neuroplasticity in stroke recovery can inform the development of more effective rehabilitation interventions and improve outcomes for individuals affected by stroke.
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41

Du, Wenbin, Jiamin Shen i Tong Su. "Neuroplasticity in Stroke Rehabilitation: Harnessing Brain’s Adaptive Capacities for Enhanced Recovery". Journal of Innovations in Medical Research 2, nr 11 (listopad 2023): 50–58. http://dx.doi.org/10.56397/jimr/2023.11.07.

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This paper explores the role of neuroplasticity in stroke rehabilitation, emphasizing the significance of individualized approaches for enhanced recovery outcomes. Stroke, as a neurological event, introduces challenges that prompt adaptive responses within the brain. Neuroplasticity, defined by synaptic rewiring, axonal sprouting, and cortical reorganization, becomes a foundational concept for designing effective rehabilitation strategies. The essentials of neuroplasticity are examined, considering immediate and long-term adaptive responses post-stroke. Traditional rehabilitation methods, particularly physical therapy and cognitive interventions, are reevaluated in the context of their impact on neuroplastic changes. Case studies highlight instances where neuroplasticity contributes to motor and cognitive recovery, showcasing the importance of personalized interventions. Challenges in predicting adaptive outcomes and understanding patient-specific neuroplasticity are addressed, prompting a call for continuous refinement in rehabilitation strategies. Looking forward, the paper discusses the future implications of precision rehabilitation, technological advancements, and interdisciplinary collaboration. The role of individualized approaches is underscored as pivotal in maximizing the potential of neuroplasticity and ensuring meaningful, sustainable recovery aligned with each patient’s unique needs and aspirations.
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42

Penna, Leandro Goursand, João Pascoa Pinheiro, Sergio Henrique Rodolpho Ramalho i Carlos Fontes Ribeiro. "Effects of aerobic physical exercise on neuroplasticity after stroke: systematic review". Arquivos de Neuro-Psiquiatria 79, nr 9 (wrzesień 2021): 832–43. http://dx.doi.org/10.1590/0004-282x-anp-2020-0551.

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ABSTRACT Background: Stroke is among the leading causes of death and disability worldwide. Interventions for stroke rehabilitation aim to minimize sequelae, promote individuals’ independence and potentially recover functional damage. The role of aerobic exercise as a facilitator of post-stroke neuroplasticity in humans is still questionable. Objective: To investigate the impact of aerobic exercise on neuroplasticity in patients with stroke sequelae. Methods: A systematic review of randomized clinical trials and crossover studies was performed, with searches for human studies in the following databases: PUBMED, EMBASE, LILACS and PeDRO, only in English, following the PRISMA protocol. The keywords used for selecting articles were defined based on the PICO strategy. Results: This systematic review evaluated the impacts of aerobic exercise on neuroplasticity through assessment of neural networks and neuronal excitability, neurotrophic factors, or cognitive and functional assessment. Studies that evaluated the effects of aerobic exercise on neuroplasticity after stroke measured through functional resonance (fMRI) or cortical excitability have shown divergent results, but aerobic exercise potentially can modify the neural network, as measured through fMRI. Additionally, aerobic exercise combined with cognitive training improves certain cognitive domains linked to motor learning. Studies that involved analysis of neurotrophic factors to assess neuroplasticity had conflicting results. Conclusions: Physical exercise is a therapeutic intervention in rehabilitation programs that, beyond the known benefits relating to physical conditioning, functionality, mood and cardiovascular health, may also potentiate the neuroplasticity process. Neuroplasticity responses seem more robust in moderate to high-intensity exercise training programs, but dose-response heterogeneity and non-uniform neuroplasticity assessments limit generalizability.
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Kossut, Małgorzata. "Basic mechanism of neuroplasticity". Neuropsychiatria i Neuropsychologia 14, nr 1-2 (2019): 1–8. http://dx.doi.org/10.5114/nan.2019.87727.

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Fernandez-Espejo, Emilio, i Nieves Rodriguez-Espinosa. "Psychostimulant Drugs and Neuroplasticity". Pharmaceuticals 4, nr 7 (30.06.2011): 976–91. http://dx.doi.org/10.3390/ph4070976.

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Palm, Ulrich, Moussa A. Chalah i Samar S. Ayache. "Brain Stimulation and Neuroplasticity". Brain Sciences 11, nr 7 (30.06.2021): 873. http://dx.doi.org/10.3390/brainsci11070873.

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Electrical or magnetic stimulation methods for brain or nerve modulation have been widely known for centuries, beginning with the Atlantic torpedo fish for the treatment of headaches in ancient Greece, followed by Luigi Galvani’s experiments with frog legs in baroque Italy, and leading to the interventional use of brain stimulation methods across Europe in the 19th century [...]
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Murciano-Brea, Julia, Martin Garcia-Montes, Stefano Geuna i Celia Herrera-Rincon. "Gut Microbiota and Neuroplasticity". Cells 10, nr 8 (13.08.2021): 2084. http://dx.doi.org/10.3390/cells10082084.

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The accumulating evidence linking bacteria in the gut and neurons in the brain (the microbiota–gut–brain axis) has led to a paradigm shift in the neurosciences. Understanding the neurobiological mechanisms supporting the relevance of actions mediated by the gut microbiota for brain physiology and neuronal functioning is a key research area. In this review, we discuss the literature showing how the microbiota is emerging as a key regulator of the brain’s function and behavior, as increasing amounts of evidence on the importance of the bidirectional communication between the intestinal bacteria and the brain have accumulated. Based on recent discoveries, we suggest that the interaction between diet and the gut microbiota, which might ultimately affect the brain, represents an unprecedented stimulus for conducting new research that links food and mood. We also review the limited work in the clinical arena to date, and we propose novel approaches for deciphering the gut microbiota–brain axis and, eventually, for manipulating this relationship to boost mental wellness.
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47

Ewing, Gillian. "From Neuroplasticity to Scaffolding". International Journal of User-Driven Healthcare 2, nr 2 (kwiecień 2012): 24–43. http://dx.doi.org/10.4018/ijudh.2012040104.

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This paper is a review of cognitive aging research centred on the Scaffolding Theory of Aging and Cognition (STAC), a theory which brings together much of the previous research into cognitive aging over the past century and suggests directions for future work. From Santiago Ramon y Cajal, with his microscope and talented drawings, to today’s researchers with psychological and neurobiological methods and technology, particularly neuroimaging techniques, such as fMRI, sMRI, PET, etc., enormous progress has been made, through cognitive reserve, dedifferentiation, compensation, hemispherical asymmetry, inhibition and neurotransmission, to the Scaffolding theory of aging and cognition and beyond. Prior to 1990, research was almost entirely behavioural, but the advent of neuroimaging has boosted research and given rise to a new domain known as cognitive neuroscience, combining behavioural and neurobiological approaches to investigate structural and functional changes in the aging brain. Having reviewed the existing literature on cognitive aging research, the author concludes that although the scaffolding theory brings together a significant body of work and ideas, it is not yet the single, unifying theory for researchers. However, it does represent a giant step toward that theory.
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Bezzola, Ladina, Susan Mérillat i Lutz Jäncke. "Motor Training-Induced Neuroplasticity". GeroPsych 25, nr 4 (styczeń 2012): 189–97. http://dx.doi.org/10.1024/1662-9647/a000070.

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The present lab-review presents and discusses our previous and current research into motor training-induced neuroplasticity by classifying our work on the basis of two broad aspects: (1) the applied study design (i.e., cross-sectional vs. longitudinal) and (2) the complexity of the motor task subjected to training (i.e., elementary finger movements vs. highly complex physical activity). Together with others we demonstrate that training-induced anatomic and functional changes are evident for a wide range of motor tasks and for several age cohorts. Finally, we discuss our findings from a lifespan perspective and embed them in the context of research investigating the beneficial effect of motor training-induced neuroplasticity on brain aging.
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Tedesco, Vincenzo, Chiara Ravagnani, Daniele Bertoglio i Cristiano Chiamulera. "Acute ketamine-induced neuroplasticity". NeuroReport 24, nr 7 (maj 2013): 388–93. http://dx.doi.org/10.1097/wnr.0b013e32836131ad.

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Liu, Cun-Zhi, Jian Kong i KeLun Wang. "Acupuncture Therapies and Neuroplasticity". Neural Plasticity 2017 (2017): 1–2. http://dx.doi.org/10.1155/2017/6178505.

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