Building Biocompatible Hydrogels for Tissue Engineering of the Brain and Spinal Cord

Aurand, Emily R.; Wagner, Jennifer; Lanning, Craig; Bjugstad, Kimberly B.

doi:10.3390/jfb3040839

Cited by 65 publications

(55 citation statements)

References 210 publications

(337 reference statements)

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“…For biomaterial implants containing a large number of transplanted cells, this microglial activity surrounding a graft may or may not be beneficial depending on whether the microglia are assisting microvessel formation thus promoting a new blood supply to the graft, or clearing foreign material. However, the glial scar formed around an injury to the CNS by reactive astrocytes [18,19], including an injury left by a needle tract [16,20,21], is broadly considered to hinder axon growth and thus would hinder the ability of the graft to integrate with the host tissue during neuron replacement therapies for PD. Thus a polymer designed to reduce the reactivity of astrocytes may be beneficial, but it is not clear how this could inherently be achieved.…”

Section: Toxicity and Host Responsementioning

confidence: 99%

Prospects for polymer therapeutics in Parkinson's disease and other neurodegenerative disorders

Newland

Werner

et al. 2015

Progress in Polymer Science

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a b s t r a c tParkinson's disease (PD) is characterized by a progressive loss of dopaminergic neurons and represents a growing health burden to western societies. Like many neurodegenerative disorders the cause is unknown, however, as the pathogenesis becomes ever more elucidated, it is becoming clear that effective delivery is a key issue for new therapeutics. The versatility of today's polymerization techniques allows the synthesis of a wide range of polymer materials which hold great potential to aid in the delivery of small molecules, proteins, genetic material or cells. In this review, we capture the recent advances in polymer based therapeutics of the central nervous system (CNS). We place the advances in historical context and, furthermore, provide future prospects in line with newly discovered advancements in the understanding of PD and other neurodegenerative disorders. This review provides researchers in the field of polymer chemistry and materials science an up-to-date understanding of the requirements placed upon materials designed for use in the CNS aiding the focus of polymer therapeutic design.

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Section: Toxicity and Host Responsementioning

confidence: 99%

Prospects for polymer therapeutics in Parkinson's disease and other neurodegenerative disorders

Newland

Werner

et al. 2015

Progress in Polymer Science

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“…While the hydrogels used in these two studies are very similar in chemistry, neither study provides enough detail about the tunable properties to be independently replicated. Hydrogel chemistry and subsequent physical and mechanical properties all have unique contributions to successful tissue engineering, specifically with regard to the reaction of the host tissue to the hydrogel and how replacement cells respond to hydrogel encapsulation (Aurand et al, 2012a,b). A comprehensive exploration of hydrogels well suited for neural tissue engineering, composed of commercially available materials with defined tunable properties may help standardize the use of hydrogels for neural tissue repair.…”

Section: Introductionmentioning

confidence: 99%

“…HA is the main polymer backbone of the extracellular matrix (ECM) of the brain and is degraded by hyaluronidases produced by both neurons and glia in vivo (Al'Qteishat et al, 2006; Lindwall et al, 2013). Biologically inert PEG provides additional control over hydrogel physical properties and helps to enhance functionality through prefabrication of more complex polymers, allowing for the attachment of cells or incorporation of growth factors or drugs (Aurand et al, 2012a,b; Burdick et al, 2006; Lampe et al, 2011; Lin and Anseth, 2009; Lin et al, 2009, 2011; Sawhney et al, 1993; Young and Engler, 2011). Our study employs only these two components, without further modifications, to assess baseline biocompatibility and explore how changes in hydrogel polymer ratio and subsequent physical and mechanical properties affect the fate of encapsulated neural progenitor cells (NPC).…”

Section: Introductionmentioning

confidence: 99%

“…Hydrogel biocompatibility is improved when the mechanical properties of the hydrogel are matched to the host tissue (Aurand et al, 2012a,b; Banerjee et al, 2009; Engler et al, 2006; Georges et al, 2006; Saha et al, 2008; Seidlits et al, 2010; Teixeira et al, 2009). Since tissue-matching is an important quality of a successful hydrogel, we investigated the fate of both fetal- and adult-derived NPC in twenty-five different HA and PEG hydrogels.…”

Section: Introductionmentioning

confidence: 99%

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Hydrogel formulation determines cell fate of fetal and adult neural progenitor cells

et al. 2014

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Hydrogels provide a unique tool for neural tissue engineering. These materials can be customized for certain functions, i.e. to provide cell/drug delivery or act as a physical scaffold. Unfortunately, hydrogel complexities can negatively impact their biocompatibility, resulting in unintended consequences. These adverse effects may be combated with a better understanding of hydrogel chemical, physical, and mechanical properties, and how these properties affect encapsulated neural cells. We defined the polymerization and degradation rates and compressive moduli of 25 hydrogels formulated from different concentrations of hyaluronic acid (HA) and poly(ethylene glycol) (PEG). Changes in compressive modulus were driven primarily by the HA concentration. The in vitro biocompatibility of fetal-derived (fNPC) and adult-derived (aNPC) neural progenitor cells was dependent on hydrogel formulation. Acute survival of fNPC benefited from hydrogel encapsulation. NPC differentiation was divergent: fNPC differentiated into mostly glial cells, compared with neuronal differentiation of aNPC. Differentiation was influenced in part by the hydrogel mechanical properties. This study indicates that there can be a wide range of HA and PEG hydrogels compatible with NPC. Additionally, this is the first study comparing hydrogel encapsulation of NPC derived from different aged sources, with data suggesting that fNPC and aNPC respond dissimilarly within the same hydrogel formulation.

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“…Apart from their biomedical use (e.g., contact lenses, wound dressings, drug delivery devices (Caló and Khutoryanskiy, 2015)), hydrogels have found their way into cell culture labs (Altmann et al, 2009;Andersen et al, 2015;Tibbitt and Anseth, 2009) and tissue engineering (Baroli, 2007;Kim et al, 2011;Leal-Egaña et al, 2013;Hunt et al, 2014). In the latter context, they serve as circuit reconstruction scaffolds for the timed orchestration of events in (neuro)development, as drug delivery devices or as cell encapsulation constituents for implantation (Aurand et al, 2012a(Aurand et al, , 2012bCarballo-Molina and Velasco, 2015;McMurtrey, 2015). There are several categories of gelling agents to choose from.…”

Section: Introductionmentioning

confidence: 99%

Selective comparison of gelling agents as neural cell culture matrices for long-term microelectrode array electrophysiology

Wilk

Habibey

Golabchi

et al. 2016

OCL

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-In classic monolayer cell culture, the world is flat. In contrast, tissue-embedded cells experience a threedimensional context to interact with. We assessed a selection of natural gelling agents of non-animal origin (ι-and κ-carrageenan, gellan gum, guar gum, locust bean gum, sodium alginate, tragacanth and xanthan gum) in serum-free medium at 1-4% (w/v) concentration for their suitability as a more natural 3D culture environment for brain-derived cells. Their biophysical properties (viscosity, texture, transparency, gelling propensity) resemble those of the extracellular matrix (ECM). Gels provide the neurons with a 3D scaffold to interact with and allow for an increase of the overall cell density compared to classical monolayer 2D culture. They not only protect neurons in cell culture from shear forces and medium evaporation, but stabilize the microenvironment around them for efficient glial proliferation, tissue-analog neural differentiation and neural communication. We report on their properties (viscosity, transparency), their ease of handling in a cell culture context and their possible use modalities (cell embedment, as a cell cover or as a cell culture substrate). Among the selected gels, guar gum and locust bean gum with intercalated laminin allowed for cortical cell embedment. Neurons plated on and migrating into gellan gum survived and differentiated even without the addition of laminin. Sodium alginate with laminin was a suitable cell cover. Finally, we exemplarily demonstrate how guar gum supported the functional survival of a cortical culture over a period of 79 days in a proof-of-concept long-term microelectrode array (MEA) electrophysiology study.Keywords: Microbial-, plant-and algae-derived gelling agents / 3D neural cell culture / microelectrode array electrophysiology Résumé -Comparaison sélective d'agents gélifiants utilisés en tant matrices de cultures de cellules neurales en 3 dimensions pour une approche à long terme d'électrophysiologie. Au contraire de la culture classique pratiquée en monocouche (2D), la culture cellulaire en 3 dimensions (3D) permet de reproduire les interactions entre cellules d'un tissu. Nous avons évalué une sélection d'agents gélifiants naturels d'origine non animale (ι-et κ-carraghénane, gomme gellane, gomme de guar, gomme de caroube, alginate de sodium, gomme adragante et gomme de xanthane) dans un milieu sans sérum à des concentrations de 1-4 % (w/v) au regard de leur aptitude à offrir un milieu de culture 3D plus naturel pour les cellules cérébrales. Les propriétés biophysiques de ces agents (viscosité, texture, transparence, propension de gélification) ressemblent à celles de la matrice extracellulaire. Les gels fournissent aux neurones un assemblage 3D pour interagir et permettre une augmentation de la densité cellulaire globale, comparativement à une culture monocouche 2D classique. Ils protègent non seulement les neurones en culture cellulaire des forces de cisaillement et de l'évaporation moyenne, mais stabilisent également le micro-environnement...

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Building Biocompatible Hydrogels for Tissue Engineering of the Brain and Spinal Cord

Cited by 65 publications

References 210 publications

Prospects for polymer therapeutics in Parkinson's disease and other neurodegenerative disorders

Prospects for polymer therapeutics in Parkinson's disease and other neurodegenerative disorders

Hydrogel formulation determines cell fate of fetal and adult neural progenitor cells

Selective comparison of gelling agents as neural cell culture matrices for long-term microelectrode array electrophysiology

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