Biomacromolecule conjugated nanofiber scaffold for salivary gland tissue engineering

Xerostomia or dry mouth, resulting from loss of salivary gland secretion can be alleviated by tissue engineering approaches to restore glandular cell function. Engineering an artificial salivary gland structure requires closely mimicking the natural environment, both physically and functionally, to promote epithelial cell proliferation, monolayer formation and apico-basal polarization. While the physical structure of the salivary gland extracellular matrix (ECM) can be reconstructed using biocompatible nanofiber scaffolds, the chemical signals from ECM macromolecules are equally involved in the gland morphogenesis. In these glands, Hyaluronic acid (HA), a biomacromolecule that is a major component of the ECM, plays a crucial role in recruiting growth factors to improve cell viability and growth in these glands. Another molecule of interest that improved salivary epithelial cell viability and apico-basal differentiation is laminin, a major protein found in the basement membrane. We hypothesize that these biomacromolecules, when conjugated nanofiber scaffolds, will provide the essential chemical signals that promote cell viability, proliferation, polarity in the salivary cell line of interest. These morphological changes will in turn promote the secretory function (salivary production). The nanofiber scaffold consisting of poly(lactic-co-glycolic)acid is conjugated with HA using a polyethylene glycol (PEG) diamine crosslinker. This conjugation was confirmed using fluorescence spectrometry, water contact angle test and immunocytochemistry analysis using confocal microscopy. The effect of HA in promoting cell survival in-vitro was established with MTT assay using SIMS (mouse submandibular immortalized ductal SIMS cells) cells. The effect of HA in improving the apico - basal polarity of SIMS cells will be assessed. Chemical modification of synthetic nanopolymeric scaffolds with ECM molecules e.g., HA, laminin are the next step towards developing "smart scaffolds", that can be used to specifically induce proper salivary gland function. These scaffolds can potentially be used to provide a viable approach for creating future artificial tissue engineered glands.