Interactions of copolymeric poly(glyceryl methacrylate)-collagen hydrogels with neural tissue: effects of structure and polar groups

Microscopic Structure of Swollen Hydrogels by Scanning Electron and Light Microscopies: Artifacts and Reality

The exact knowledge of hydrogel microstructure, mainly its pore topology, is a key issue in hydrogel engineering. For visualization of the swollen hydrogels, the cryogenic or high vacuum scanning electron microscopies (cryo-SEM or HVSEM) are frequently used while the possibility of artifact-biased images is frequently underestimated. The major cause of artifacts is the formation of ice crystals upon freezing of the hydrated gel. Some porous hydrogels can be visualized with SEM without the danger of artifacts because the growing crystals are accommodated within already existing primary pores of the gel. In some non-porous hydrogels the secondary pores will also not be formed due to rigid network structure of gels that counteracts the crystal nucleation and growth. We have tested the limits of true reproduction of the hydrogel morphology imposed by the swelling degree and mechanical strength of gels by investigating a series of methacrylate hydrogels made by crosslinking polymerization of glycerol monomethacrylate and 2-hydroxyethyl methacrylate including their interpenetrating networks. The hydrogel morphology was studied using cryo-SEM, HVSEM, environmental scanning electron microscopy (ESEM), laser scanning confocal microscopy (LSCM) and classical wide-field light microscopy (LM). The cryo-SEM and HVSEM yielded artifact-free micrographs for limited range of non-porous hydrogels and for macroporous gels. A true non-porous structure was observed free of artifacts only for hydrogels exhibiting relatively low swelling and high elastic modulus above 0.5 MPa, whereas for highly swollen and/or mechanically weak hydrogels the cryo-SEM/HVSEM experiments resulted in secondary porosity. In this contribution we present several cases of severe artifact formation in PHEMA and PGMA hydrogels during their visualization by cryo-SEM and HVSEM. We also put forward empirical correlation between hydrogel morphological and mechanical parameters and the occurrence and intensity of artifacts.

3D in vitro modeling of the central nervous system

There are currently more than 600 diseases characterized as affecting the central nervous system (CNS) which inflict neural damage. Unfortunately, few of these conditions have effective treatments available. Although significant efforts have been put into developing new therapeutics, drugs which were promising in the developmental phase have high attrition rates in late stage clinical trials. These failures could be circumvented if current 2D in vitro and in vivo models were improved. 3D, tissue-engineered in vitro systems can address this need and enhance clinical translation through two approaches: (1) bottom-up, and (2) top-down (developmental/regenerative) strategies to reproduce the structure and function of human tissues. Critical challenges remain including biomaterials capable of matching the mechanical properties and extracellular matrix (ECM) composition of neural tissues, compartmentalized scaffolds that support heterogeneous tissue architectures reflective of brain organization and structure, and robust functional assays for in vitro tissue validation. The unique design parameters defined by the complex physiology of the CNS for construction and validation of 3D in vitro neural systems are reviewed here.

Change in neuron aggregation and neurite fasciculation on EVAL membranes modified with different diamines

In this study, we modified poly(ethylene-co-vinyl alcohol) (EVAL) membranes by the covalent bonding of diamines via epoxidation of surface hydroxyl groups of EVAL to analyze the effect of immobilized diamines with different carbon chain length on the cultured cerebellar granule neurons. Morphological studies showed that neurons seeded on the diamine-immobilized EVAL membrane were able to survive and regenerate with formation of an extensive neuritic network. Furthermore, cultured neurons showed that the presence of diamine with different carbon chain length was able to effectively regulate the neuron adhesion, migration, aggregation, and neurite growth pattern, but mediated neuronal activity with equal efficacy. The short-chain amine stimulated neuron migration, aggregation, and neurite fasciculation, whereas the long carbon chain diamine maintained single neuron distribution with the defasciculated feature of the neurite. Although it is known that positively charged amine molecules can interact directly with cell surface proteoglycans to mediate cell attachment, this study further demonstrated that the terminal primary amine with different carbon chain length is involved in mediating cell-substrate interaction to further regulate neuron aggregation and neurite fasciculation. This indicates a delicate interaction of neuron with the immobilized diamine molecules on the EVAL membrane surface. This work is encouraging because the diamine- immobilized EVAL membranes can be applied for the establishment of different neural culture systems useful for future investigations of neuron biology under in vitro conditions.

Superior survival and durability of neurons and astrocytes on 3-dimensional aragonite biomatrices

Current needs of central nervous system therapy urge for the identification of scaffolds supporting the generation and long-term maintenance of healthy and functional neuronal tissue. We compared for the first time the viability of hippocampal neurons and astrocytes grown on conventional 2-dimensional (2D) conditions with that of cells grown on an aragonite bioactive 3-dimensional (3D) scaffold prepared from coralline exoskeleton. Cultures in 3D showed significantly lower mortality rate and higher neurons/astrocytes ratio than 2D cultures. Moreover, whereas cell survival in 2D was arrested in the absence of the supporting substrates poly-D-lysine and laminin, these substrates had negligible effect on the 3D cultures. Furthermore, aragonite matrices supported cell survival and growth under conditions of calcium and nutrients deprivation, whereas in 2D such treatments led to death of all neurons and of almost all astrocytes. To show that the aragonite matrices are permissive for neural cells also in vivo, aragonite matrices having no substrate coating grafted into postnatal rat cortex were invaded by neurons growing on the surface and in multilayer structures resembling those seen in the 3D culture in vitro. Hence, culture of neurons and astrocytes on 3D aragonite coralline matrices is a novel mean for production of stable neuronal tissue, with significant implication to the field of neuronal tissue restoration.

Structural analysis of dextran-based hydrogels obtained chemoenzymatically

This work reports the results of structural analysis in novel dextran-acrylate (dexT70-VA) hydrogels generated chemoenzymatically. Porous structure as well as hydrogel surface and interior morphologies were evaluated by mercury intrusion porosimetry (MIP), nitrogen adsorption (NA), and scanning electron microscopy (SEM) analyses, as a function of the degree of substitution (DS), and initial water content used in the preparation of the hydrogel. MIP analysis showed that the overall networks were clearly macroporous with pore sizes ranging from 0.065 to 10 microm. As expected, the average pore size decreased as DS increased and as initial water content decreased. Moreover, the porosity values ranged from 75 up 90%, which shows that these hydrogels present an interconnected pore structure. Nitrogen adsorption analyses showed that the specific surface area of dexT70-VA hydrogels increased either by increasing the DS or by decreasing the initial water content of the hydrogel. SEM results revealed that the surface of hydrogels with lower DS presented either a porous structure or a polymeric "skin" covering the pores, whereas hydrogels with higher DS were totally porous. Furthermore, the interior morphology varied according to the DS and the initial water content of the hydrogels. Finally, the average pore size was also determined from the swelling of hydrogel using a theoretical model developed by Flory-Rehner. The comparison of the SEM and MIP results with the ones obtained by the equilibrium swelling theory of Flory-Rehner shows that this approach highly underestimates the average pore size.

Morphology and gelation of thermosensitive chitosan hydrogels

The morphology of physical hydrogels is often difficult to examine due to the delicate nature of the system and therefore has not been studied in detail. Chitosan/GP (glycerophosphate salt) is a significant hydrogel in the biomedical and cosmetic fields as it is thermosensitive and contains less than 5% polysaccharide. The morphology of this system was examined with laser scanning confocal microscopy (LSCM) to image the gel morphology. The images indicate that the gel is quite heterogeneous, and power spectra reveal a fractal-like morphology. A study of composition found that increasing chitosan concentration increased the amount of polymer-rich phase present in the gel, and that the smallest aggregates decreased in size.

Semi-synthetic collagen/poloxamine matrices for tissue engineering

Collagen-containing poloxamine hydrogels were produced with the aim of overcoming the low stiffness displayed by collagen gels that are not otherwise chemically crosslinked. Matrices were obtained by functionalization of a four-arm PEO-PPO block copolymer (poloxamine, Tetronic) with methcrylate groups and subsequent free radical polymerization of water solutions of the modified polymer in the presence of collagen. The resulting matrices had a sharp increase in stiffness, when compared to pure collagen gels. For example, whereas collagen had a storage modulus (G') around 70 Pa and a loss modulus (G'') of 10 Pa, a crosslinked collagen/poloxamine system containing 8.3% crosslinked poloxamine had G' and G'' values of 7400 and 1000 Pa, respectively. HepG2 cells were seeded within the gels before the crosslinking and the viability levels estimated by AlamarBlue assay were between 65% and 91% for systems containing 0.04-0.09 wt% photoinitiator. HepG2 and endothelial cells also adhered to and spread on the surface of the collagen-containing specimens, suggesting their potential utility in tissue engineering.

Collagen/Poloxamine Hydrogels: Cytocompatibility of Embedded HepG2 Cells and Surface-Attached Endothelial Cells

The effects of cross-linked poloxamine hydrogels on the cellular function of embedded HepG2 cells and surface-attached endothelial cells were assessed. HepG2 cells embedded within collagen/poloxamine-methacrylate gel survived photo-cross-linking (MTT viability, 78%). There was a gradual increase in cell number during the first week. The cumulative secretion of alpha1-antitrypsin by HepG2 cells showed an almost linear profile. However, lower levels for the collagen/poloxamine-methacrylate matrix were observed when compared with collagen. Endothelial cells attached poorly to poloxamine gels without collagen (alamarBlue reduction ranged from 36 to 63%) and did not spread well. The addition of collagen led to spread cells and alamarBlue reduction levels of 75-93% (24 h after seeding). On day 5, some detachment was noted through analysis of vascular endothelial cadherin staining. Finally, the collagen-containing matrix was used to prepare cylindrical modules containing HepG2 cells to show the utility of this material in modular tissue constructs. A fluorescent cytoplasmic tracer, Vybrant CFDA SE, showed that embedded cells remained viable for more than 2 months, confirming the good cytocompatibility of collagen/poloxamine-methacrylate in the form of modules. The suitability of these modules for preparing uniform, scaleable, and vascularized constructs remains to be demonstrated.

Directed nerve outgrowth is enhanced by engineered glial substrates

In the present study, the influence of astrocyte alignment on the direction and length of regenerating neurites was examined in vitro. Astrocytes were experimentally manipulated by different approaches to create longitudinally aligned monolayers. When cultured on the aligned monolayers, dorsal root ganglion neurites grew parallel to the long axis of the aligned astrocytes and were significantly longer than controls. Engineered monolayers expressed linear arrays of fibronectin, laminin, neural cell adhesion molecule, and chondroitin sulfate proteoglycan that were organized parallel to one another, suggesting that a particular spatial arrangement of these molecules on the astrocyte surface may be necessary to direct nerve regeneration in vivo. In contrast, no bias in directional outgrowth was observed for neurites growing on unorganized monolayers. The results suggest that altering the organization of astrocytes and their scar-associated matrix at the lesion site may be used to influence the direction and the length of adjacent regenerating axons in the damaged brain and spinal cord.

Model porous surfaces for systematic studies of material-cell interactions

A model system for studying cell-surface interactions, based on microfabricated cell culture substrates, has been developed and is described here. Porous surfaces consisting of interconnecting channels with openings of subcellular dimensions are generated on flat, single crystal, silicon substrates. Channel size (width, depth), distribution, and surface coating can be varied independently and used for systematic investigation of how topographical, chemical, and elastic surface properties influence cell or tissue biological responses. Model porous surfaces have been produced by using two different microfabrication methods. Submicron-sized channels with very high depth-to-width aspect ratios (up to 30) have been made by using electron beam lithography and anisotropic reactive ion etching into single-crystal silicon. Another method uses thick-resist photolithography, which can be used to produce channels wider than 1 microm and with depth-to-width aspect ratios below 20 in an epoxy polymer. Preliminary cell culture tests show that fibroblasts bridge 0.8- to 1.8-microm-wide channels with very few exceptions (i.e., a continuous space below the cell-surface interface is created). It has also been shown that variation of channel periodicity significantly affects fibroblast morphology and attachment density. With this model system, it is possible to load the channels with bioactive substances intended to interact with cells at or near the surface in a time-dependent manner.

Agarose gel stiffness determines rate of DRG neurite extension in 3D cultures

The optimization of scaffold mechanical properties for neurite extension is critical for neural tissue engineering. Agarose hydrogels can be used to stimulate and maintain three-dimensional neurite extension from primary sensory ganglia in vitro. The present study explores the structure-function relationship between dorsal root ganglion (DRG) neurite extension and agarose gel mechanical properties. A range of agarose gels of differing concentrations were generated and the corresponding rate of E9 DRG neurite extension was measured. Rate of neurite extension was inversely correlated to the mechanical stiffness of agarose gels in the range of 0.75-2.00% (wt/vol) gel concentrations. In addition, we postulate a physical model that predicts the rate of neurite extension in agarose gels, if gel stiffness is a known parameter. This model is based on Heidemann and Buxbaum's model of neurite extension. These results, if extended to scaffolds of other morphological and chemical features, would contribute significantly to the design criteria of three-dimensional scaffolds for neural tissue engineering.

Preparation of EVAL membranes with smooth and particulate morphologies for neuronal culture

In this work, the in vitro interaction of cerebellar granule neurons prepared from 7-day-old Wistar rats and poly ethylene-co-vinyl alcohol (EVAL) membranes was investigated. Cells were cultured in smooth and particulate EVAL membranes for up to 7 days. Particulate membranes were prepared by using 1-octanol to precipitate EVAL solutions in DMSO. Such a membrane was microporous characterized by a packed bed of particles. Voids left between the aggregated particles formed a continuous and interconnected porous network. Crystallization of the EVAL polymer induced by 1-octanol is responsible for the formation of particulate morphology. The membrane structure and its relationship with cells were examined by scanning electron microscopy and the MTT assay. It was observed that the particulate membrane was more favorable for the neuron culture than the smooth membrane. Neurons seeded on the particulate membrane were able to regenerate with formation of an extensive neuritic network. Therefore, the particulate structure may spatially mediate cellular response that can promote neuronal cell attachment, differentiation and neuritic growth, indicating that the particulate structure should be useful as a new polymer scaffold for nerve repair.

A laminin and nerve growth factor-laden three-dimensional scaffold for enhanced neurite extension

Agarose hydrogel scaffolds were engineered to stimulate and guide neuronal process extension in three dimensions in vitro. The extracellular matrix (ECM) protein laminin (LN) was covalently coupled to agarose hydrogel using the bifunctional cross-linking reagent 1,19- carbonyldiimidazole (CDI). Compared to unmodified agarose gels, LN-modified agarose gels significantly enhanced neurite extension from three-dimensionally (3D) cultured embryonic day 9 (E9) chick dorsal root ganglia (DRGs), and PC 12 cells. After incubation of DRGs or PC 12 cells with YIGSR peptide or integrin beta1 antibody respectively, the neurite outgrowth promoting effects in LN-modified agarose gels were significantly decreased or abolished. These results indicate that DRG/PC 12 cell neurite outgrowth promoting effect of LN-modified agarose gels involves receptors for YIGSR/integrin beta1 subunits respectively. 1,2-bis(10, 12-tricosadiynoyl)-sn-glycero-3-phosphocholine (DC(8,9)PC)-based lipid microcylinders were loaded with nerve growth factor (NGF), and embedded into agarose hydrogels. The resulting trophic factor gradients stimulated directional neurite extension from DRGs in agarose hydrogels. A PC 12 cell-based bioassay demonstrated that NGF-loaded lipid microcylinders can release physiologically relevant amounts of NGF for at least 7 days in vitro. Agarose hydrogel scaffolds may find application as biosynthetic 3D bridges that promote regeneration across severed nerve gaps.

Characterization of cortical astrocytes on materials of differing surface chemistry

The behavior of cortical astrocytes was evaluated on a number of medically relevant materials of differing physicochemical properties. This study describes cell attachment, DNA synthesis, production of extracellular matrix (ECM) proteins, and neuronal interactions of perinatal rat astrocytes in vitro. The number of attached astrocytes initially differed among the materials, decreasing with increasing material hydrophobicity. In contrast, the rate of DNA synthesis increased with increasing material hydrophobicity. With the exception of only one material, astrocytes reached confluence by 12 days in culture on all the materials tested. Furthermore, the expression of characteristic ECM proteins and the fundamental ability of astrocytes to support neuronal attachment and growth was qualitatively identical between populations of astrocytes on different materials. The ability of astrocytes to colonize different surfaces initially was mediated via adsorbed serum proteins, as reducing the capacity of a model surface to adsorb proteins inhibited astrocyte colonization for up to 2 weeks in culture. We propose that astrocytes are relatively insensitive to differences in surface chemistries so long as the proteins necessary for cellular attachment are capable of adsorbing to the material to some extent. It seems likely that the ability of astrocytes to produce and remodel a matrix creates a surface environment that eventually becomes similar regardless of the surface chemistry of the underlying material.

Biological reactions to cerebrospinal fluid shunt devices: a review of the cellular pathology

OBJECTIVE

To understand the interaction between cerebrospinal fluid shunt components and the brain and other tissues.

METHODS

A systematic review of the medical literature directly pertaining to shunt complications, and that dealing with tissues' reactions to implants in general, was conducted.

RESULTS

Vascularized pedicles of glial tissue or choroid plexus grow into ventricular catheters, primarily as a mechanical phenomenon. Cellular debris or blood can cause dysfunction of valve components. Chronic inflammation, which is nonspecific, might contribute to degradation of the components.

CONCLUSION

Care must be taken to prevent early entry of debris or blood into the shunt system. Ventricular collapse onto the shunt must be avoided. Refinement of manufacturing methods or modification of shunt materials could reduce the susceptibility of shunts to infection and improve longevity of the apparatus.

PC12 cell aggregation and neurite growth in gels of collagen, laminin and fibronectin

PC12 cells form aggregates when suspended within three-dimensional, self-assembled, type I collagen gels; these aggregates increase in size over time. In addition, when the cells are cultured in the presence of nerve growth factor, they express neurites, which extend through the three-dimensional matrix. In this report, the roles of fibronectin, laminin and nerve growth factor in PC12 cell aggregation and neurite growth following suspension in collagen matrices were evaluated. Single cells and small clusters of cells were suspended in collagen gels; the kinetics of aggregation were determined by measurement of the projected area of each aggregate, and neurite lengths were determined by measurement of end-to-end distance. Fibronectin and laminin inhibited the aggregation of PC12 cells at 50 micrograms/ml, and fibronectin, but not laminin, inhibited the growth of neurites at 100 micrograms/ml. In the absence of serum, the aggregation of cells cultured with nerve growth factor was almost completely inhibited, but the average neurite length was unaffected. In the presence of nerve growth factor, the extent of cell aggregation could not be explained simply by an increase in cell number, suggesting the presence of two separate mechanisms for aggregate growth: one dependent on cell motility and another dependent on cell proliferation.

Recent developments of collagen-based materials for medical applications and drug delivery systems

In this review, an attempt was made to summarize some of the recent developments in the application of collagen as a biomaterial and in drug delivery systems. The main applications covered include: collagen for burn/wound cover dressings; osteogenic and bone filling materials; antithrombogenic surfaces; and immobilization of therapeutic enzymes. Recently, collagen used as a carrier for drug delivery has attracted many researchers throughout the world. The use of collagen for various drug delivery systems has also been reviewed in this article. Collagen-based drug delivery systems include: injectable microspheres based on gelatin (degraded form of collagen); implantable collagen-synthetic polymer hydrogels; interpenetrating networks of collagen; and synthetic polymers collagen membranes for ophthalmic delivery. Recent efforts to use collagen-liposomal composites for controlled drug delivery, as well as collagen as controlling membranes for transdermal delivery, were also reviewed. In this review, the main emphasis was on the work done in our laboratory.

Axonal growth within poly (2-hydroxyethyl methacrylate) sponges infiltrated with Schwann cells and implanted into the lesioned rat optic tract

Porous hydrophilic sponges made from 2-hydroxyethyl methacrylate (HEMA) have a number of possible biomedical applications. We have investigated whether these poly(HEMA) hydrogels, when coated with collagen and infiltrated in vitro with cultured Schwann cells, can be implanted into the lesioned optic tract and act as prosthetic bridges to promote axonal regeneration. Nineteen rats (20-21 days old) were given hydrogel/Schwann cell implants. No obvious toxic effects were seen, either to the transplanted glia or in the adjacent host tissue. Schwann cells survived the implantation technique and were immunopositive for the low affinity nerve growth factor receptor, S100 and laminin. Immunohistochemical studies showed that host non-neuronal cells (astrocytes, oligodendroglia and macrophages) migrated into the implanted hydrogels. Astrocytes were the most frequently observed host cell in the polymer bridges. RT97-positive axons were seen in about two thirds of the implants. The axons were closely associated with transplanted Schwann cells and, in some cases, host glia (astrocytes). Individual axons regrowing within the implanted hydrogels could be traced for up to 900 microns, showing that there was continuity in the network of channels within the polymer scaffold. Axons did not appear to be myelinated by either Schwann cells or by migrated host oligodendroglia. In three rats, anterograde tracing with WGA/HRP failed to demonstrate the presence of retinal axons within the hydrogels. The data indicate that poly(HEMA) hydrogels containing Schwann cells have the potential to provide a stable three-dimensional scaffold which is capable of supporting axonal regeneration in the damaged CNS.

Evaluation of two cross-linked collagen gels implanted in the transected spinal cord

In previous experiments, we have shown that spinal axons grow into a collagen matrix implanted between the stumps of a transected spinal cord. However, the matrix became denatured after 2 to 3 months. To improve the stability and the durability of the collagen gel implants, collagen was coprecipitated with chondroitin-6-sulfate (C-6-S) or chemically cross-linked with carbodiimide (CD). The spinal cords were taken out after 3 days, 1, 3, or 6 months and analyzed using different histological and tracing techniques. The cross-linked collagen matrices underwent major structural changes. Cross-linking treatments improved the stability of collagen implants which withstood at least 6 months. Axons revealed with DiI or silver staining crossed the proximal interface and grew into the bioimplants. Some axons were also followed across the distal bioimplant-spinal interface in DiI treated tissues. This study suggests that cross-linking the collagen hydrogel has improved the mechanical properties of the matrix, modified the normal scarring process, and favored axonal regeneration.

Synthetic polymer derivatives as substrata for neuronal adhesion and growth

The adhesion and viability of dissociated neurons of rat cerebral hemispheres onto methacrylate and methacrylamide hydrogels, either unmodified or containing collagen, basement membrane proteins, and glucosamine, were measured in vitro. The degree of cell adhesion was affected by properties of the polymers such as hydrophilicity, hydrophobicity, presence of reactive chemical groups, and incorporation of biological molecules. Adhesion was promoted by attachment of glucosamine to the polymer backbone. Viability was enhanced by the presence of basement membrane proteins within the polymer network. Morphological studies of cells seeded, both onto and within the polymeric matrices, demonstrated the capacity of such substrates to support neuritic outgrowth. The potential of these in vitro assays in the design of polymeric matrices as neural tissue repair promoter substrate is discussed.