The promise of low-tech intervention in a high-tech era: Remodeling pathological brain circuits using behavioral reverse engineering

Daniel B. Polley, Daniela Schiller

Research output: Contribution to journalReview articlepeer-review

9 Scopus citations

Abstract

As an academic pursuit, neuroscience is enjoying a golden age. From a clinical perspective, our field is failing. Conventional 20th century drugs and devices are not well-matched to the heterogeneity, scale, and connectivity of neural circuits that produce aberrant mental states and behavior. Laboratory-based methods for editing neural genomes and sculpting activity patterns are exciting, but their applications for hundreds of millions of people with mental health disorders is uncertain. We argue that mechanisms for regulating adult brain plasticity and remodeling pathological activity are substantially pre-wired, and we suggest new minimally invasive strategies to harness and direct these endogenous systems. Drawing from studies across the neuroscience literature, we describe approaches that identify neural biomarkers more closely linked to upstream causes—rather than downstream consequences—of disordered behavioral states. We highlight the potential for innovation and discovery in reverse engineering approaches that refine bespoke behavioral “agonists” to drive upstream neural biomarkers in normative directions and reduce clinical symptoms for select classes of neuropsychiatric disorders.

Original languageEnglish
Article number104652
JournalNeuroscience and Biobehavioral Reviews
Volume137
DOIs
StatePublished - Jun 2022

Keywords

  • Biomarker
  • Brain training
  • Clinical trials
  • Cognitive behavioral therapy
  • Digital therapeutic
  • Neurobehavioral therapy
  • PTSD, tinnitus, hyperacusis, sensory overload, traumatic memory
  • Reconsolidation

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