Bundling of axons through a capillary alginate gel enhances the detection of axonal action potentials using microelectrode arrays

George, Dale; Anderson, Wesley A.; Sommerhage, Frank; Willenberg, Alicia; Hines, Rebecca; Bosak, Alexander; Willenberg, Bradley J.; Lambert, Stephen

doi:10.1002/term.2793

Cited by 7 publications

(7 citation statements)

References 46 publications

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“…iPSC-derived neurons are generally considered phenotypically immature and have distinct genomic profiles that will need to be accounted for in the transition to human cell-based systems. Furthermore, serum-free culture of rat DRGs is feasible (Anderson et al, 2018;George et al, 2019), and we are currently making the transition to serum-free culture.…”

mentioning

confidence: 99%

Modeling chemotherapy-induced peripheral neuropathy using a Nerve-on-a-chip microphysiological system

Kramer

Nguyen

Jacobs

et al. 2020

ALTEX

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CIPN), which is rapidly induced after the administration of anti-cancer drugs (Argyriou et al., 2012; Cavaletti and Marmiroli, 2010). Patients with CIPN may experience a range of sensory symptoms including spontaneous tingling, burning pain, and joint and muscle pain in the distal extremities in a "glove and stocking" distribution (Peters et al., 2007). Often, these side effects discourage patient use of the drug, leading to delays or limited dosages and even discontinued treatment altogether (Staff et al., 2017). In some patients, these symptoms resolve following discontinuation of therapy, but an estimated 30% of patients are left with permanent symptoms that affect their overall quality of life (Rivera and Cianfrocca, 2015). Drugs with neurotoxic side effects reaching market approval is attributed to a lack of reliable screens for drug candidate neurotoxicity.Traditional methods for studying neuronal damage and screening neurotoxicity have largely relied on cell and animal models

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mentioning

confidence: 99%

Modeling chemotherapy-induced peripheral neuropathy using a Nerve-on-a-chip microphysiological system

Kramer

Nguyen

Jacobs

et al. 2020

ALTEX

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“…Stiff, laminin-coated glass beads used as a 3D network positioned above an MEA showed variant burst rates and stimulus-evoked responses compared with 2D culture of e18 rat hippocampal neurons (Frega et al 2014). Softer substrates, such as anisotropic alginate-based scaffolds (Anderson et al 2018;George et al 2019) or carbon nanotube-containing PDMS (Bosi et al 2015), have also shown varied activity including capabilities of delineating capsaicin-dependent spikes of peripheral nerve culture and improving overall hippocampal neuron activity, respectively. With 3D systems outperforming 2D, future development should surround exploring further how 3D systems may affect arborization (Kayal et al 2019), synaptic maturation and functional activity, especially in the presence of drugs.…”

Section: Functional Assessmentmentioning

confidence: 99%

“…and 3D bioprinted substrates (Antill-O'Brien et al 2019) in order to recreate aspects of 3D macrostructure or neural connectivity seen in the brain. The peripheral nerve has also seen advancements in growing explant or spheroid cultures within anisotropic materials(Anderson et al 2018;George et al 2019) and growth restrictive hydrogels(Huval et al 2015;Nguyen et al 2019;Sharma et al 2019;Kramer et al 2020), respectively. Ultimately, the inherent qualities of anatomical histoarchitecture should guide the design of microarchitectural features of microphysiological devices.…”

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confidence: 99%

Advances in 3D neuronal microphysiological systems: towards a functional nervous system on a chip

Anderson

Bosak

Högberg

et al. 2021

In Vitro Cell.Dev.Biol.-Animal

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Microphysiological systems (MPS) designed to study the complexities of the peripheral and central nervous systems have made marked improvements over the years and have allowed researchers to assess in two and three dimensions the functional interconnectivity of neuronal tissues. The recent generation of brain organoids has further propelled the field into the nascent recapitulation of structural, functional, and effective connectivities which are found within the native human nervous system. Herein, we will review advances in culture methodologies, focused especially on those of human tissues, which seek to bridge the gap from 2D cultures to hierarchical and defined 3D MPS with the end goal of developing a robust nervous system-on-a-chip platform. These advances have far-reaching implications within basic science, pharmaceutical development, and translational medicine disciplines.

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“…Inks should possess appropriate, tunable bioactivity and porosity to facilitate robust colonization by target cells (i.e., biocompatible) [ 4 , 8 , 9 , 10 , 11 ]. Inspired by the pioneering work developing microgels as biomaterial inks by Burdick et al [ 12 , 13 , 14 ], we hypothesized that capillary alginate gel (Capgel) tissue scaffolds are ideal candidate biomaterials than can be readily transformed to meet this need [ 15 , 16 , 17 , 18 , 19 , 20 , 21 ].…”

Section: Introductionmentioning

confidence: 99%

“…These scaffolds were then cut into smaller Capgel pieces and loaded into a syringe for printing/extrusion ( Section 4.3 and Section 4.4 ). Various Capgels that have been successful in a wide range of tissue engineering applications include: 3D stem cell culture scaffolds [ 19 ], injectable stem cell delivery [ 20 ], in vitro construction of functional nerve [ 17 , 18 ], and as injectable wound healing biomaterials [ 15 , 16 ].…”

Section: Introductionmentioning

confidence: 99%

Transforming Capillary Alginate Gel (Capgel) into New 3D-Printing Biomaterial Inks

Panarello

Seavey

Doshi

et al. 2022

Gels

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Three-dimensional (3D) printing has great potential for creating tissues and organs to meet shortfalls in transplant supply, and biomaterial inks are key components of many such approaches. There is a need for biomaterial inks that facilitate integration, infiltration, and vascularization of targeted 3D-printed structures. This study is therefore focused on creating new biomaterial inks from self-assembled capillary alginate gel (Capgel), which possesses a unique microstructure of uniform tubular channels with tunable diameters and densities. First, extrusions of Capgel through needles (0.1–0.8 mm inner diameter) were investigated. It was found that Capgel ink extrudes as slurries of fractured and entangled particles, each retaining capillary microstructures, and that extruded line widths W and particle sizes A were both functions of needle inner diameter D, specifically power-law relationships of W~D0.42 and A~D1.52, respectively. Next, various structures were successfully 3D-printed with Capgel ink, thus demonstrating that this biomaterial ink is stackable and self-supporting. To increase ink self-adherence, Capgel was coated with poly-L-lysine (PLL) to create a cationic “skin” prior to extrusion. It was hypothesized that, during extrusion of Capgel-PLL, the sheared particles fracture and thereby expose cryptic sites of negatively-charged biomaterial capable of forming new polyelectrolyte bonds with areas of the positively-charged PLL skin on neighboring entangled particles. This novel approach resulted in continuous, self-adherent extrusions that remained intact in solution. Human lung fibroblasts (HLFs) were then cultured on this ink to investigate biocompatibility. HLFs readily colonized Capgel-PLL ink and were strongly oriented by the capillary microstructures. This is the first description of successful 3D-printing with Capgel biomaterial ink as well as the first demonstration of the concept and formulation of a self-adherent Capgel-PLL biomaterial ink.

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Bundling of axons through a capillary alginate gel enhances the detection of axonal action potentials using microelectrode arrays

Cited by 7 publications

References 46 publications

Modeling chemotherapy-induced peripheral neuropathy using a Nerve-on-a-chip microphysiological system

Modeling chemotherapy-induced peripheral neuropathy using a Nerve-on-a-chip microphysiological system

Advances in 3D neuronal microphysiological systems: towards a functional nervous system on a chip

Transforming Capillary Alginate Gel (Capgel) into New 3D-Printing Biomaterial Inks

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