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          and reorganization of brain networks during   25(8):877-883; 2015.
          normal and abnormal development. J. Child   88.  Wassermann, E. M.; Zimmermann, T.
          Psychol. Psychiatry 56(3):299-320; 2015.     Transcranial magnetic brain stimulation: thera-
      85.  Walhovd, K. B.; Fjell, A. M.; Espeseth, T.   peutic promises and scientific gaps. Pharmacol.
          Cognitive decline and brain pathology in aging–  Ther. 133(1):98-107; 2012.
          need for a dimensional, lifespan and systems   89.  Wassermann, E. M. Inter-and intra-individual
          vulnerability view. Scand. J. Psychol. 55(3):244-  variation in the response to TMS. The Oxford
          254; 2014.                                    handbook of transcranial magnetic stimulation.
      86.  Wang, J. X.; Rogers, L. M.; Gross, E. Z.; Ryals, A.   Oxford, UK: Oxford UP; 2008:401-408.
          J.; Dokucu, M. E.; Brandstatt, K. L.; Hermiller,   90.  Zheng, X.; Schlaug, G. Structural white matter
          M. S.; Voss, J. L. Targeted enhancement of corti-  changes in descending motor tracts correlate
          cal-hippocampal brain networks and associative   with improvements in motor impairment after
          memory. Science 345(6200):1054-1057; 2014.    undergoing a treatment course of tDCS and
      87.  Wang, J. X.; Voss, J. L. Long-lasting enhance-  physical therapy. Front. Hum. Neurosci. 9; 2015.
          ments of memory and hippocampal-cortical
          functional connectivity following multiple-day
          targeted noninvasive stimulation. Hippocampus