Soft hydrazone crosslinked hyaluronan- and alginate-based hydrogels as 3D supportive matrices for human pluripotent stem cell-derived neuronal cells
Introduction
Traumas and deficits in the human central nervous system (CNS) may have a permanent effect on the functionality of the patient and the prognosis in many cases is poor. Moreover, human CNS, as an organ, suffers from low inbuilt regenerative capacity, which makes healing with traditional medicine (drugs and surgical operations) insufficient. As a result, regenerative medicine is considered to be a potential treatment for CNS deficits. Regenerative medicine aims to restore normal functionality by enhancing the regeneration of tissue or by replacing the damaged parts with engineered biological transplants. One such strategy is cell therapy combined with a supportive biomaterial scaffold.
Biomaterial scaffold should fulfill specific criteria when they are used for neural tissue engineering with the aim of neuronal network regeneration. For example, the scaffolds should have similar mechanical properties to those of the brain or spinal cord, they should allow the infiltration of cells and axons, they should allow the transportation of nutrients and metabolites, they should integrate with the host tissue, they should exhibit a suitable degradation rate without any harmful degradation products, and they should not induce inflammatory and glial scar formation [1]. Based on these requirements, polymer-based hydrogels can be considered to be suitable biomaterial candidates for neural tissue engineering. A soft, hydrated form of three-dimensional crosslinked hydrogels resembles that of naturally occurring living tissue. The porous nature of hydrogels enables the transportation of waste, oxygen and nutrients. The mechanical and physical properties of hydrogels are tunable making it easier to mimic the living tissue [2]. Most hydrogels are also considered to be cyto- and biocompatible materials.
When designing hydrogels for this kind of application, a thorough knowledge of their various properties is important. Hydrogels have variable mechanical, physical and degradation properties that can be controlled, for example, by altering the molecular weight (Mw), the chemical structure and the number of available crosslinkable groups in the polymer, the ratio of gel components, the amount of water, and the crosslinking method. It is well known that, for example, crosslinking density can affect mechanical, swelling and degradation properties and the functionality of hydrogels. The difficulty lies in the altering of properties individually when needed without affecting the others [3]. Further modification of hydrogels can be carried out by incorporating extracellular matrix (ECM) molecules (collagen, laminin, etc.) or peptides to provide more anchoring sites for the cells [4], [5].
Numerous natural and synthetic polymer-based hydrogels have been used as scaffolds for the 3D culture of neural lineage cells as reviewed by, for example, Murphy et al. [2]. Two widely used polysaccharide polymers used in neural research are hyaluronan (HA) [6], [7] and alginate [8], [9]. HA is an anionic and hydrophilic polysaccharide composed of β-1, 4-d-glucuronic acid and β-1, 3-N-acetyl-d-glycosamine residues that is a major glycosaminoglycan component in the ECM of the brain. HA plays a vital role in the development of the CNS, and it is particularly abundant in the fetal brain and the surrounding immature neurons during differentiation in the spinal cord [10]. HA is produced by almost all the members of the animal kingdom as well as certain members of the streptococci species. It has a relatively simple repetitive chemical structure. The carboxyl and hydroxyl groups allow specific modification and the introduction of functional groups for crosslinking. Alginate (AL) is an anionic and hydrophilic polysaccharide composed of 1,4-linked β -d-mannuronic acid (M) and α -l-guluronic acid (G) residues that is obtained from brown algae. It is structurally similar to ECM. AL is inherently non-biodegradable, but it can be made degradable, for example, by replacing the divalent cations with monovalent cations or by oxidation [11]. The properties of natural polymer-based hydrogels can be improved and widened by combining them with a synthetic polymer such as polyvinyl alcohol (PVA). PVA is a hydrophilic polymer with good chemical, thermal and mechanical stability. Hydroxyl groups in the structure provide chemical versatility that enables further modification and functionalization [12]. Biocompatible PVA hydrogels have been used quite widely in several biomedical applications [13]. PVA has also been approved by the Food and Drug Administration (FDA) and Conformité Européenne (CE) for clinical use in humans [14].
HA-PVA and AL-PVA hydrogels can be fabricated by using hydrazone crosslinking, which is an aldehyde-hydrazide coupling reaction. Hydrazone crosslinking belongs to the group of pseudo click chemistry reactions together with the Michael addition reaction (pseudo is usually characterized by moderate orthogonality). The reactions are versatile, simple and reversible, and they have high reactivity and yield. Furthermore, no toxic reagents or side-products are produced [15]. This crosslinking method also enables the fabrication of injectable hydrogels. The injectability of the hydrogels is desirable for when the hydrogels are eventually transplanted into the injury site. To date, there have been several studies carried out on hydrazone crosslinked HA-PVA hydrogels [16], [17]. The focus of these studies has, however, been on other areas of soft tissue engineering. To the best of our knowledge, this is the first time the polymerization and properties of the hydrazone crosslinked AL-PVA hydrogel have been reported.
In this study, we have produced injectable hydrazone crosslinked HA-PVA and AL-PVA hydrogels with variable properties. We studied the effect of the degree of substitution (DS%), the molecular weight of the polymer components and the polymer concentration of the hydrogel on swelling, degradation and the mechanical properties of the hydrogels. We also studied the effects of the above parameters on the growth of human pluripotent stem cell-derived neuronal cells.
Section snippets
Materials and general methods
Hyaluronic acid sodium salt (Mw = 1.5 × 105 g/mol) was purchased from Lifecore (Chaska, MN, USA). Hyaluronic acid sodium salt from streptococcus equi (Mw = 1.5 − 1.8 × 106 g/mol), polyvinyl alcohol (Mw=27000 g/mol, 98.0 –98.8 % hydrolyzed), t-butyl carbazate (TBC), 1,1 ′ - carbonyldiimidazole (CDI), glycine ethyl ester hydrochloride, hydrazine solution (35 wt % in H2O), 1-hydroxybenzotriazole (HOBt), alginic acid sodium salt from brown algae (low viscosity), picrylsulfonic acid solution (5-% (w/v) in H2O,
Modification of hyaluronan, alginate and polyvinyl alcohol with complementary reactive groups
The polymers were modified with complementary reactive groups to attain aldehyde-modified HA (HAALD) and alginate (ALALD), and hydrazide-modified PVA (PVAHY) with relatively low DS%, in order to not lose the characteristic properties of the polymers. Hyaluronan and alginate were periodate oxidized to obtain one ALALD component and four HAALD components with variable DS% (Table 1). The modification was confirmed with 1H-NMR and FTIR analysis. In the 1H-NMR spectrum of HAALD (Fig. 1), the
Conclusions
In summary, injectable hydrazone crosslinked HA-PVA and AL-PVA hydrogels were produced and their detailed properties were investigated. To the best of our knowledge, the polymerization and properties of hydrazone crosslinked AL-PVA hydrogel are reported for the first time. The degree of substitution and molecular weight of the polymer components as well as the polymer concentration of the hydrogel were shown to affect to the swelling, degradation and mechanical properties of the hydrogels.
Acknowledgments
This work was funded by TEKES (the Finnish Funding Agency for Innovation) Human Spare Parts project, the Finnish Cultural Foundation grant numbers 00140325 and 00150312, and by the Academy of Finland grant number 286990. The authors would like to thank Ph.D. Mari Hämäläinen (University of Tampere Medical School) for providing the rabbit tissue samples. The authors would also like to thank Ph.D. Alexandre Efimov and Laboratory Attendant Anne-Maarit Tikkanen (Faculty of Natural Sciences,
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