Engineered Axonal Tracts as “Living Electrodes” for Synaptic‐Based Modulation of Neural Circuitry

Serruya, Mijail; Harris, Jerome S.; Adewole, Dayo O.; Struzyna, Laura A.; Burrell, Justin C.; Nemes, Ashley D.; Petrov, Dmitriy; Kraft, Reuben H.; Chen, H. Isaac; Wolf, John A.; Cullen, D. Kacy

doi:10.1002/adfm.201701183

Cited by 39 publications

(35 citation statements)

References 137 publications

(265 reference statements)

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“…Micro-TENNs as a Platform Technology for Brain Pathway Reconstruction or as "Living Electrodes"[1],[4]-[6]. (A) Micro-TENNs initially consist of a 3D hydrogel cylinder (gray) encasing an extracellular matrix core of collagen and laminin (red), to date measuring up to several centimeters in length.…”

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confidence: 99%

Assessing functional connectivity across 3D tissue engineered axonal tracts using calcium fluorescence imaging

et al. 2018

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To our knowledge, this is the first report using directed transfer function and transfer entropy methods based on fluorescent calcium activity to estimate functional connectivity of distinct neuronal populations via long-projecting, 3D axonal tracts in vitro. These functional data will further improve the design and optimization of implantable neural networks that could ultimately be deployed to reconstruct the nervous system to treat neurological disease and injury.

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confidence: 99%

Assessing functional connectivity across 3D tissue engineered axonal tracts using calcium fluorescence imaging

et al. 2018

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“…In a different fabrication process, we have created engineered constructs called micro-TENNs that consist of an aggregate of neurons seeded within the collagen-filled lumen of a hydrogel micro-column (345-710 μm in diameter) and projecting millimeter-to centimeter-scale aligned axonal tracts (Fig. 4a, b) 19,21,[207][208][209][210] . These micro-TENNs have been traditionally designed for minimally invasive implantation in the CNS featuring neurons isolated from the cerebral cortex ( Fig.…”

Section: Micro-tissue Engineered Neural Network As a Tool For Localimentioning

confidence: 99%

“…4c-e) or the ventral midbrain ( Fig. 4f-i) for applications in cortical-thalamic pathway reconstruction 208 and as synaptic-based interfaces with cortical circuitry 210,211 , or as replacements for the degenerated nigrostriatal pathway in Parkinson's disease 21 , respectively. These constructs replicate the structure of axonal pathways projecting from a discrete neuronal population, and thus may also mimic the ganglia-axon tract architecture in the PNS/ANS.…”

Section: Micro-tissue Engineered Neural Network As a Tool For Localimentioning

confidence: 99%

“…d, e High magnification images of the aggregate and axon tract regions of the micro-TENN construct, respectively. (Reprinted with permission from Serruya et al 210 ; authors of content, John Wiley and Sons). f Bidirectional micro-TENN at 14 days fabricated with an aggregate of rat embryonic ventral midbrain neurons (left) and striatal neurons (right) and stained for dopaminergic neurons (tyrosine hydroxylase (TH); red), medium spiny (striatal) neurons (DARPP-32; green), synapses (synapsin I; purple), and nuclei (Hoechst; blue).…”

Section: Challenges and Advancements Towards Fabricating Innervated Tmentioning

confidence: 99%

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Innervation: the missing link for biofabricated tissues and organs

et al. 2020

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Innervation plays a pivotal role as a driver of tissue and organ development as well as a means for their functional control and modulation. Therefore, innervation should be carefully considered throughout the process of biofabrication of engineered tissues and organs. Unfortunately, innervation has generally been overlooked in most non-neural tissue engineering applications, in part due to the intrinsic complexity of building organs containing heterogeneous native cell types and structures. To achieve proper innervation of engineered tissues and organs, specific host axon populations typically need to be precisely driven to appropriate location(s) within the construct, often over long distances. As such, neural tissue engineering and/or axon guidance strategies should be a necessary adjunct to most organogenesis endeavors across multiple tissue and organ systems. To address this challenge, our team is actively building axon-based "living scaffolds" that may physically wire in during organ development in bioreactors and/or serve as a substrate to effectively drive targeted long-distance growth and integration of host axons after implantation. This article reviews the neuroanatomy and the role of innervation in the functional regulation of cardiac, skeletal, and smooth muscle tissue and highlights potential strategies to promote innervation of biofabricated engineered muscles, as well as the use of "living scaffolds" in this endeavor for both in vitro and in vivo applications. We assert that innervation should be included as a necessary component for tissue and organ biofabrication, and that strategies to orchestrate host axonal integration are advantageous to ensure proper function, tolerance, assimilation, and bio-regulation with the recipient post-implant.

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“…15,19 To date, micro-TENNs have been fabricated using dorsal root ganglia neurons, cerebral cortical neurons (e.g., mixed glutamatergic and GABAergic), embryonic rodent ventral mesencephalic dopaminergic neurons, and human ESC-derived dopaminergic neurons. 5,125,126,129,[141][142][143][144] As our understanding of PD pathophysiology expands, it is possible that multiple micro-TENNs could be transplanted to reconnect different damaged regions, comprised of alternative neuronal phenotypes, such as noradrenergic, serotoninergic, and cholinergic cell types. However, it is difficult to predict how transplant therapies, including either transplanted cells or pathways, such as micro-TENNs, could be used to recapitulate widely dispersed innervation of cerebral cortex from cholinergic, serotonergic, or noradrenergic brainstem nuclei.…”

Section: Tissue Engineering: Combining Cells and Scaffoldsmentioning

confidence: 99%

Emerging regenerative medicine and tissue engineering strategies for Parkinson’s disease

Harris

Burrell

Struzyna

et al. 2020

npj Parkinsons Dis.

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Parkinson’s disease (PD) is the second most common progressive neurodegenerative disease, affecting 1–2% of people over 65. The classic motor symptoms of PD result from selective degeneration of dopaminergic neurons in the substantia nigra pars compacta (SNpc), resulting in a loss of their long axonal projections to the striatum. Current treatment strategies such as dopamine replacement and deep brain stimulation (DBS) can only minimize the symptoms of nigrostriatal degeneration, not directly replace the lost pathway. Regenerative medicine-based solutions are being aggressively pursued with the goal of restoring dopamine levels in the striatum, with several emerging techniques attempting to reconstruct the entire nigrostriatal pathway—a key goal to recreate feedback pathways to ensure proper dopamine regulation. Although many pharmacological, genetic, and optogenetic treatments are being developed, this article focuses on the evolution of transplant therapies for the treatment of PD, including fetal grafts, cell-based implants, and more recent tissue-engineered constructs. Attention is given to cell/tissue sources, efficacy to date, and future challenges that must be overcome to enable robust translation into clinical use. Emerging regenerative medicine therapies are being developed using neurons derived from autologous stem cells, enabling the construction of patient-specific constructs tailored to their particular extent of degeneration. In the upcoming era of restorative neurosurgery, such constructs may directly replace SNpc neurons, restore axon-based dopaminergic inputs to the striatum, and ameliorate motor deficits. These solutions may provide a transformative and scalable solution to permanently replace lost neuroanatomy and improve the lives of millions of people afflicted by PD.

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Engineered Axonal Tracts as “Living Electrodes” for Synaptic‐Based Modulation of Neural Circuitry

Cited by 39 publications

References 137 publications

Assessing functional connectivity across 3D tissue engineered axonal tracts using calcium fluorescence imaging

Assessing functional connectivity across 3D tissue engineered axonal tracts using calcium fluorescence imaging

Innervation: the missing link for biofabricated tissues and organs

Emerging regenerative medicine and tissue engineering strategies for Parkinson’s disease

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