H Isaac Chen1, John A Wolf, Douglas H Smith. 1. Department of Neurosurgery, Perelman School of Medicine University of Pennsylvania, Philadelphia, PA 19104, United States of America. Philadelphia Veterans Affairs Medical Center, Philadelphia, PA 19104, United States of America.
Abstract
OBJECTIVE: Although substantial progress has been made in mapping the connections of the brain, less is known about how this organization translates into brain function. In particular, the massive interconnectivity of the brain has made it difficult to specifically examine data transmission between two nodes of the connectome, a central component of the 'neural code.' Here, we investigated the propagation of multiple streams of asynchronous neuronal activity across an isolated in vitro 'connectome unit.' APPROACH: We used the novel technique of axon stretch growth to create a model of a long-range cortico-cortical network, a modular system consisting of paired nodes of cortical neurons connected by axon tracts. Using optical stimulation and multi-electrode array recording techniques, we explored how input patterns are represented by cortical networks, how these representations shift as they are transmitted between cortical nodes and perturbed by external conditions, and how well the downstream node distinguishes different patterns. MAIN RESULTS: Stimulus representations included direct, synaptic, and multiplexed responses that grew in complexity as the distance between the stimulation source and recorded neuron increased. These representations collapsed into patterns with lower information content at higher stimulation frequencies. With internodal activity propagation, a hierarchy of network pathways, including latent circuits, was revealed using glutamatergic blockade. As stimulus channels were added, divergent, non-linear effects were observed in local versus distant network layers. Pairwise difference analysis of neuronal responses suggested that neuronal ensembles generally outperformed individual cells in discriminating input patterns. SIGNIFICANCE: Our data illuminate the complexity of spiking activity propagation in cortical networks in vitro, which is characterized by the transformation of an input into myriad outputs over several network layers. These results provide insight into how the brain potentially processes information and generates the neural code and could guide the development of clinical therapies based on multichannel brain stimulation.
OBJECTIVE: Although substantial progress has been made in mapping the connections of the brain, less is known about how this organization translates into brain function. In particular, the massive interconnectivity of the brain has made it difficult to specifically examine data transmission between two nodes of the connectome, a central component of the 'neural code.' Here, we investigated the propagation of multiple streams of asynchronous neuronal activity across an isolated in vitro 'connectome unit.' APPROACH: We used the novel technique of axon stretch growth to create a model of a long-range cortico-cortical network, a modular system consisting of paired nodes of cortical neurons connected by axon tracts. Using optical stimulation and multi-electrode array recording techniques, we explored how input patterns are represented by cortical networks, how these representations shift as they are transmitted between cortical nodes and perturbed by external conditions, and how well the downstream node distinguishes different patterns. MAIN RESULTS: Stimulus representations included direct, synaptic, and multiplexed responses that grew in complexity as the distance between the stimulation source and recorded neuron increased. These representations collapsed into patterns with lower information content at higher stimulation frequencies. With internodal activity propagation, a hierarchy of network pathways, including latent circuits, was revealed using glutamatergic blockade. As stimulus channels were added, divergent, non-linear effects were observed in local versus distant network layers. Pairwise difference analysis of neuronal responses suggested that neuronal ensembles generally outperformed individual cells in discriminating input patterns. SIGNIFICANCE: Our data illuminate the complexity of spiking activity propagation in cortical networks in vitro, which is characterized by the transformation of an input into myriad outputs over several network layers. These results provide insight into how the brain potentially processes information and generates the neural code and could guide the development of clinical therapies based on multichannel brain stimulation.
Authors: Bryan J Pfister; Akira Iwata; Andrew G Taylor; John A Wolf; David F Meaney; Douglas H Smith Journal: J Neurosci Methods Date: 2005-12-05 Impact factor: 2.390
Authors: Liangbin Pan; Sankaraleengam Alagapan; Eric Franca; Stathis S Leondopulos; Thomas B DeMarse; Gregory J Brewer; Bruce C Wheeler Journal: Front Neural Circuits Date: 2015-07-14 Impact factor: 3.492
Authors: Anjali Vijay Dhobale; Dayo O Adewole; Andy Ho Wing Chan; Toma Marinov; Mijail D Serruya; Reuben H Kraft; D Kacy Cullen Journal: J Neural Eng Date: 2018-06-01 Impact factor: 5.379
Authors: H Isaac Chen; Dennis Jgamadze; James Lim; Kobina Mensah-Brown; John A Wolf; Jason A Mills; Douglas H Smith Journal: Tissue Eng Part A Date: 2019-03-29 Impact factor: 3.845
Authors: D Kacy Cullen; Wisberty J Gordián-Vélez; Laura A Struzyna; Dennis Jgamadze; James Lim; Kathryn L Wofford; Kevin D Browne; H Isaac Chen Journal: iScience Date: 2019-10-03