Lactone-layered double hydroxide networks: Towards self-assembled bioscaffolds

Zhou, Tianhao; McCarthy, Edward D.; Soutis, C.; Cartmell, Sarah H.

doi:10.1016/j.clay.2017.11.044

Cited by 7 publications

(6 citation statements)

References 27 publications

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“…These methods often exploit light-induced photopolymerization where, for instance, photosensitive resins cured by a light source (often a UV light source) are used to prime and support the polymerization. Light-induced polymerization is also widely employed in a vast range of modern technological applications, ranging from coatings , to lithographic processes and the fabrication of bioscaffolds. − This technology has gained much popularity over alternative methods (such as thermally induced polymerization) due to its reasonable cost, high accuracy and spatial control of the curing process, and improved sustainability, due to the lower use of volatile organic components.…”

Section: Introductionmentioning

confidence: 99%

Capturing Free-Radical Polymerization by SynergeticAb InitioCalculations and Topological Reactive Molecular Dynamics

et al. 2022

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Photocurable polymers are used ubiquitously in 3D printing, coatings, adhesives, and composite fillers. In the present work, the free radical polymerization of photocurable compounds is studied using reactive classical molecular dynamics combined with a dynamical approach of the nonequilibrium molecular dynamics (D-NEMD). Different concentrations of radicals and reaction velocities are considered. The mechanical properties of the polymer resulting from 1,6-hexanediol dimethacrylate systems are characterized in terms of viscosity, diffusion constant, and activation energy, whereas the topological ones through the number of cycles (polymer loops) and cyclomatic complexity. Effects like volume shrinkage and delaying of the gel point for increasing monomer concentration are also predicted, as well as the stress–strain curve and Young’s modulus. Combining ab initio, reactive molecular dynamics, and the D-NEMD method might lead to a novel and powerful tool to describe photopolymerization processes and to original routes to optimize additive manufacturing methods relying on photosensitive macromolecular systems.

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Section: Introductionmentioning

confidence: 99%

Capturing Free-Radical Polymerization by SynergeticAb InitioCalculations and Topological Reactive Molecular Dynamics

et al. 2022

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“…LC INSOL, a lactone copolymer network (PN) with fewer carboxylic units per monomer than poly(lactic acid) was synthesized according to the method described in Zhou et al (2018). This copolymer PN was subjected to immersion in the culture medium described above.…”

Section: Resultsmentioning

confidence: 99%

“…The lactone PN LC INSOL was selected from nine other PNs synthesized in a previous study (Zhou, McCarthy, Soutis, & Cartmell, 2018) as the optimal one for use in osteogenesis due to its high polymer mass yield and high magnesium content; a schematic of the LC INSOL preparation process is given in Figure 1 (Zhou et al, 2018). This comprised the polymerization of a mixture of monomer(s) plus LDH followed by dissolution of the product in methylene chloride.…”

Section: Sample Preparationmentioning

confidence: 99%

Novel lactone‐layered double hydroxide ionomer powders for bone tissue repair

et al. 2020

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This article describes the use of a novel lactone‐layered double hydroxide polymer network (PN), derived from a poly(lactide‐co‐caprolactone) copolymer, as a controlled ion‐release agent for artificial bone tissue regeneration. The osteogenic cell culture Saos‐2 is used as a test culture to investigate the PN's performance as an extracellular ion‐release agent. The compelling performance of this PN is demonstrated in both growth and osteogenic media compared with a control of cells grown on tissue culture plastic (TCP) without PN. Firstly, the PNs released concentration of magnesium ions over time ranging from 10 to 60 mM after 24 hr, depending on the PN sample. After incubation of Saos‐2 with the PN, while no difference was seen in cell number, there was significant upregulation of bone‐related gene expression at 14 days—~5fold increase in Bone Morphogenetic Protein 2, ~3fold increase in osteopontin and ~2fold increase in collagen Type I. In addition, normalized alkaline phosphatase activity was seen to significantly increase by ~2fold with PN presence. A ~4fold increase in collagen Type I protein expression (via Gomori Trichrome Stain) was observed with PN presence. In addition, a ~4fold increase in phosphate deposits (as seen with Von Kossa staining analysis) was seen with PN presence. It is found that this novel PN material has a significant potential for bone tissue regeneration.

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“…These assemblies permit also to shed light on the role of the prebiotic organization of key structural building blocks before the presence of membrane-separated systems; [27] in particular, it has been crucial the role of clays and layered double hydroxides [28][29][30] in the molecular origin of life on Earth, and also on the role of liquid/liquid phase separation in the complex organization via the condensation of the molecular machineries inside eukaryotic cells leading to membranelless organelles. [31][32][33] By increasing complexity, bottom-up synthetic biology develops artificial compartments enclosed by nanoscopic membranes including assemblies enclosed by lipidic or polymeric membranes (liposomes [34] and polymersomes [35] , respectively), oil-in-water [36][37][38][39] and water-inoil [40] emulsions stabilized by amphiphilic membranes, inorganic nanoparticles (colloidosomes [41,42] ) or protein-polymer capsules (proteinosomes [43,44] ).…”

Section: Introductionmentioning

confidence: 99%

Artificial Biosystems by Printing Biology

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Ferrara

Bonasera

et al. 2020

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The continuous progress of printing technologies over the past 20 years has fueled the development of a wide plethora of applications in materials sciences, flexible electronics and biotechnologies. More recently, printing methodologies have started up to explore the world of Artificial Biology, offering new paradigms in the direct assembly of Artificial Biosystems (small condensates, compartments, networks, tissues and organs) by mimicking the result of the evolution of living systems and also by redesigning natural biological systems, taking inspiration from them. This recent progress is reported in terms of a new field here defined as Printing Biology, resulting from the intersection between the field of printing and the bottom up Synthetic Biology. Printing Biology explores new approaches for the reconfigurable assembly of designed lifelike or life-inspired structures. This review presents this emerging field, highlighting its main features, i.e. printing methodologies (from 2D to 3D), molecular ink properties, deposition mechanisms, and finally the applications and future challenges. Printing Biology is expected to show a growing impact on the development of biotechnology and lifeinspired fabrication. Printing Biology employs different technologies dispensing molecular inks with tunable composition (molecules, polymers, biomolecules) and drop sizes (from nano-up to macroscale) onto solids or into liquids to develop lifelike or life-inspired artificial biosystems (from small condensates, to compartments up to networks, tissues and organs). This work reviews the extraordinary potential of this emerging research field.

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Lactone-layered double hydroxide networks: Towards self-assembled bioscaffolds

Cited by 7 publications

References 27 publications

Capturing Free-Radical Polymerization by SynergeticAb InitioCalculations and Topological Reactive Molecular Dynamics

Capturing Free-Radical Polymerization by SynergeticAb InitioCalculations and Topological Reactive Molecular Dynamics

Novel lactone‐layered double hydroxide ionomer powders for bone tissue repair

Artificial Biosystems by Printing Biology

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