Patterning human neuronal networks on photolithographically engineered silicon dioxide substrates functionalized with glial analogues

Abstract: Interfacing neurons with silicon semiconductors is a challenge being tackled through various bioengineering approaches. Such constructs inform our understanding of neuronal coding and learning and ultimately guide us toward creating intelligent neuroprostheses. A fundamental prerequisite is to dictate the spatial organization of neuronal cells. We sought to pattern neurons using photolithographically defined arrays of polymer parylene-C, activated with fetal calf serum. We used a purified human neuronal cell l… Show more

“…To imitate native interfacial areas and to create cell gradients and transitional populations, multiphasic scaffolds are investigated ( Figure A,B), with a particular interest in skin, the osteochondral and bone‐to‐ligament/tendon interfaces . Modified topographies, patterned surfaces and anisotropic scaffolds were deemed to improve the functionality of specific cell types such as smooth muscle cells or neurons . However, controlling topography and porosity of the scaffold in the context of coculture is more challenging, as cocultured cells do not necessarily present the same physiological features.…”

“…For instance, keratinocytes and fibroblasts are used for construction of skin substitutes . In other cases, however, such as regeneration of the nervous system, the cell types diverge from one study to another . Cocultured cells can be located within the same native tissue, for instance the osteoblast/chondrocyte gradient in the osteochondral interface, or heterotopic cell sources can be used to trigger relevant mechanisms in vitro.…”

“…Currently, there is no effective way to even partially restore the nervous system functions after spinal cord transection . Development of scaffolds‐based TEC can address some challenges of neuronal tissue engineering, namely, remyelination of rebuilt nerves, their patterns, alignment, and anisotropy through appropriate biomaterial designs. Direct cell injections into the injured area without a scaffold produced mitigating effects regarding guided differentiation, as the injected neural stem cells tended to differentiate into astrocytes instead of neurons and oligodendrocytes .…”

Multilineage Constructs for Scaffold‐Based Tissue Engineering: A Review of Tissue‐Specific Challenges

“…To imitate native interfacial areas and to create cell gradients and transitional populations, multiphasic scaffolds are investigated ( Figure A,B), with a particular interest in skin, the osteochondral and bone‐to‐ligament/tendon interfaces . Modified topographies, patterned surfaces and anisotropic scaffolds were deemed to improve the functionality of specific cell types such as smooth muscle cells or neurons . However, controlling topography and porosity of the scaffold in the context of coculture is more challenging, as cocultured cells do not necessarily present the same physiological features.…”

“…For instance, keratinocytes and fibroblasts are used for construction of skin substitutes . In other cases, however, such as regeneration of the nervous system, the cell types diverge from one study to another . Cocultured cells can be located within the same native tissue, for instance the osteoblast/chondrocyte gradient in the osteochondral interface, or heterotopic cell sources can be used to trigger relevant mechanisms in vitro.…”

“…Currently, there is no effective way to even partially restore the nervous system functions after spinal cord transection . Development of scaffolds‐based TEC can address some challenges of neuronal tissue engineering, namely, remyelination of rebuilt nerves, their patterns, alignment, and anisotropy through appropriate biomaterial designs. Direct cell injections into the injured area without a scaffold produced mitigating effects regarding guided differentiation, as the injected neural stem cells tended to differentiate into astrocytes instead of neurons and oligodendrocytes .…”

Multilineage Constructs for Scaffold‐Based Tissue Engineering: A Review of Tissue‐Specific Challenges

“…One of the core challenges is to engineer a long-term sympathetic connection between the key processing components of neurons (ion channels) and those of electronics (electrodes and transistors). Several groups approach this challenge by trying to gain topographic control of the neuron or neurite (in an environment promoting long-term survival) and using this to guide its engagement with electrodes 9, 10, 11, 12, 13, 14…”

Insinuating electronics in the brain

“…Neurites instead grew out onto the surrounding SiO 2 in a manner that suggested attraction to nearby cell clusters, possible mediated by an as yet unidentified chemotactic gradient. problematic [36]. Moreover, the presence of the template cell itself complicates creation of a suitable interface between neuron and silicon.…”

Towards a ‘siliconeural computer’: technological successes and challenges