7 research outputs found
Cytocompatibility of Novel Algae-PLA Membranes For Guided Bone Regeneration At The Level of Types I, III And V Collagen Expression
Statement of the problem: In recent years, the development of innovative
and increasingly optimized barrier membranes has focused on marine algae,
which as a biopolymer can form a membrane composite together with
polylactic acid, thus a combination could show numerous advantages such as
antioxidant, antitumor, antibacterial, antiviral as well as antiallergic properties.
Furthermore, algae can be produced in an ecologically sustainable way and offer
an alternative for patients who refuse treatment with bovine or porcine derived
membranes due to ethical or religious reasons.Objective: In this study, four different algal membranes were evaluated
for their cytocompatibility with cultured human fibroblasts and osteoblasts.Materials & Methods: Mem-Lok® (Collagen Matrix, New Jersey, USA)
as a resorbable collagen membrane and ArgonautTM (Botiss Biomaterials, Zossen,
Germany) as a native pericardium GBR/GTR membrane served as reference
membranes (RMs). As the negative control cells incubated with normal
culture medium only were used. In addition to the cell viability and proliferation
assays water soluble tetrazolium (WST), MTT and BrdU, a real time semiquantitative
real time PCR (RT-PCR) was developed to investigate in vitro cytocompatibility
at the level of types I, III and V collagen expression. A sandblasted-
large grid-acid ached titanium surface (Dentcon® Dental Implant Systems,
Ankara, Turkey) served as a positive inactive control group for osteoblastic
cytocompatibility.Results: For human osteoblasts, the algal membranes showed very good
proliferation levels in WST-1, MTT as well as BrdU, indicating cytocompatibility.
Examination of the expression behavior of type I, type III, and type V collagen
genes showed no evaluable results. However, the RT-PCR should be repeated
with the incorporated optimizations to be able to make a statement regarding
the success of bone, skin, and connective tissue regeneration after a
possible application of the membrane in maxillofacial injury treatment.Conclusion: The investigated collagen types are essential for a proper
healing of defects in both soft and bone tissue, as they have fundamental functions
such as stability and structural integrity of the tissues
Initiated Chemical Vapor Deposition (iCVD) Functionalized Polylactic Acid-Marine Algae Composite Patch for Bone Tissue Engineering
The current study aimed to describe the fabrication of a composite patch by incorporating marine algae powders (MAPs) into poly-lactic acid (PLA) for bone tissue engineering. The prepared composite patch was functionalized with the co-polymer, poly (2-hydroxyethyl methacrylate-co-ethylene glycol dimethacrylate) (p(HEMA-co-EGDMA)) via initiated chemical vapor deposition (iCVD) to improve its wettability and overall biocompatibility. The iCVD functionalized MAP-PLA composite patch showed superior cell interaction of human osteoblasts. Following the surface functionalization by p(HEMA-co-EGDMA) via the iCVD technique, a highly hydrophilic patch was achieved without tailoring any morphological and structural properties. Moreover, the iCVD modified composite patch exhibited ideal cell adhesion for human osteoblasts, thus making the proposed patch suitable for potential biomedical applications including bone tissue engineering, especially in the fields of dentistry and orthopedy
Marine Algae Incorporated Polylactide Acid Patch: Novel Candidate for Targeting Osteosarcoma Cells without Impairing the Osteoblastic Proliferation
Biodegradable collagen-based materials have been preferred as scaffolds and grafts for diverse clinical applications in density and orthopedy. Besides the advantages of using such bio-originated materials, the use of collagen matrices increases the risk of infection transmission through the cells or the tissues of the graft/scaffold. In addition, such collagen-based solutions are not counted as economically feasible approaches due to their high production cost. In recent years, incorporation of marine algae in synthetic polymers has been considered as an alternative method for preparation grafts/scaffolds since they represent abundant and cheap source of potential biopolymers. Current work aims to propose a novel composite patch prepared by blending Sargassum vulgare powders (SVP) to polylactide (PLA) as an alternative to the porcine-derived membranes. SVP-PLA composite patches were produced by using a modified solvent casting method. Following detailed material characterization to assess the cytocompatibility, human osteoblasts (HOBs) and osteosarcoma cells (SaOS-2) were seeded on neat PLA and SVP-PLA patches. MTT and BrdU assays indicated a greater cytocompatibility and higher proliferation for HOBs cultured on SVP-PLA composite than for those cultured on neat PLA. SaOS-2 cells cultured on SVP-PLA exhibited a significant decrease in cell proliferation. The composite patch described herein exhibits an antiproliferative effect against SaOS-2 cells without impairing HOBs' adhesion and proliferation