Effects of ICA on the Proliferation and Secretion of Chondrocytes in Bioscaffold Based on 3D Printing Technology

Articular cartilage plays an important role in weight-bearing and movement.However,it is also more easily damaged in intra-articular fractures.As the cartilage has no vessel and nerve,so it is hardly to repair itself once damaged seriously.Tissue engineering is a potential way to cure the cartilage damage because it combines scaffold and cells.Gels

NIR-switchable local hydrogen generation by tandem bimetallic MOFs nanocomposites for enhanced chemodynamic therapy

The inadequate quantity of hydrogen peroxide(H_(2)O_(2))in cancer cells promptly results in the constrained success of chemodynamic therapy(CDT).Significant efforts made throughout the years;nevertheless,researchers are still facing the great challenge of designing a CDT agent and securing H_(2)O_(2) supply within the tumor cell.In this study,taking advantage of H_(2)O_(2) level maintenance mechanism in cancer cells,a nanozyme-based bimetallic metal-organic frameworks(MOFs)tandem reactor is fabricated to elevate intracellular H_(2)O_(2) levels,thereby enhancing CDT.In addition,under nearinfrared excitation,the upconversion nanoparticles(UCNPs)loaded into the MOFs can perform photocatalysis and generate hydrogen,which increases cellular susceptibility to radicals induced from H_(2)O_(2),inhibits cancer cell energy,causes DNA damages and induces tumor cell apoptosis,thus improving CDT therapeutic efficacy synergistically.The proposed nanozyme-based bimetallic MOFs-mediated CDT and UCNPs-mediated hydrogen therapy act as combined therapy with high efficacy and low toxicity.

Supercritical fluid-assisted controllable fabrication of open and highly interconnected porous scaffolds for bone tissue engineering

Recently tremendous progress has been evidenced by the advancements in developing innovative three-dimensional(3 D)scaffolds using various techniques for addressing the autogenous grafting of bone. In this work, we demonstrated the fabrication of porous polycaprolactone(PCL) scaffolds for osteogenic differentiation based on supercritical fluid-assisted hybrid processes of phase inversion and foaming. This eco-friendly process resulted in the highly porous biomimetic scaffolds with open and interconnected architectures. Initially, a 2^3 factorial experiment was designed for investigating the relative significance of various processing parameters and achieving better control over the porosity as well as the compressive mechanical properties of the scaffold. Then, single factor experiment was carried out to understand the effects of various processing parameters on the morphology of scaffolds. On the other hand, we encapsulated a growth factor, i.e., bone morphogenic protein-2(BMP-2), as a model protein in these porous scaffolds for evaluating their osteogenic differentiation. In vitro investigations of growth factor loaded PCL scaffolds using bone marrow stromal cells(BMSCs) have shown that these growth factor-encumbered scaffolds were capable of differentiating the cells over the control experiments. Furthermore, the osteogenic differentiation was confirmed by measuring the cell proliferation, and alkaline phosphatase(ALP) activity, which were significantly higher demonstrating the active bone growth. Together, these results have suggested that the fabrication of growth factor-loaded porous scaffolds prepared by the eco-friendly hybrid processing efficiently promoted the osteogenic differentiation and may have a significant potential in bone tissue engineering.

Application of Supercritical Fluid Technologies in Drug Delivery System

Supercritical CO_2 technologies have been shown to have greatpotential in pharmaceutical science;they are effective in producing drug and/or polymer particles for biomedical applicationsdue to the mild critical conditions(Tc=304.1 K,Pc=7.38MPa),non-toxicity,non-flammability,and low

Supercritical fluid-assisted fabrication of C-doped Co_(3)O_(4) nanoparticles based on polymer-coated metal salt nanoreactors for efficient enzyme-mimicking and glucose sensor properties

Nanomaterials doped with non-metallic C have attracted tremendous attention as potential nano-artificial enzymes due to their ability to change the energy band structure to improve their intrinsic properties.Herein,we report a green,facile,efficient,fast strategy to access high-performance nanozymes via supercritical CO_(2)fluid technology-fabricated polymer nanoreactor of poly-(methyl vinyl ether-co-maleic anhydride)(PVM/MA)coated Co(NO_(3))_(2)into C-doped Co_(3)O_(4)(C-Co_(3)O_(4))nanozyme by a onestep calcination process.Converting PVM/MA to C doping into Co_(3)O_(4)shortens the entire lattice constant of the crystal structure,and the overall valence band energy level below the Fermi level shifts toward the lower energy direction.The as-prepared CCo_(3)O_(4)demonstrated significant peroxidase-like catalytic activity,significantly greater than the undoped Co_(3)O_(4)nanoparticle nanozyme.The following density functional theory(DFT)calculations revealed that the doped nano-enzyme catalytic site displayed a unique electronic structure,altering the material surface with more electrons to fill the anti-bond of the two molecular orbitals,significantly improving the peroxidase-like enzyme catalytic and glucose sensor performance.The resultant enzymatic glucose sensing in a linear range of 0.1–0.6 mM with a detection limit of 3.86μM is in line with standard Michaelis–Menten theory.Collectively,this work demonstrates that converting polymers into nanozymes of C-doped form by supercritical CO_(2)fluid technology in a step is an effective strategy for constructing high-performance glucose sensor nanozymes.This cost-effective,reliable,precise system offers the potential for rapid analyte detection,facilitating its application in a variety of fields.

Advances in hydrogel-based vascularized tissues for tissue repair and drug screening

The construction of biomimetic vasculatures within the artificial tissue models or organs is highly required for conveying nutrients,oxygen,and waste products,for improving the survival of engineered tissues in vitro.In recent times,the remarkable progress in utilizing hydrogels and understanding vascular biology have enabled the creation of three-dimensional(3D)tissues and organs composed of highly complex vascular systems.In this review,we give an emphasis on the utilization of hydrogels and their advantages in the vascularization of tissues.Initially,the significance of vascular elements and the regeneration mechanisms of vascularization,including angiogenesis and vasculogenesis,are briefly introduced.Further,we highlight the importance and advantages of hydrogels as artificial microenvironments in fabricating vascularized tissues or organs,in terms of tunable physical properties,high similarity in physiological environments,and alternative shaping mechanisms,among others.Furthermore,we discuss the utilization of such hydrogels-based vascularized tissues in various applications,including tissue regeneration,drug screening,and organ-on-chips.Finally,we put forward the key challenges,including multifunctionalities of hydrogels,selection of suitable cell phenotype,sophisticated engineering techniques,and clinical translation behind the development of the tissues with complex vasculatures towards their future development.

The in vitro and in vivo anti-tumor effects of MTX-Fe_3O_4-PLLA-PEG-PLLA microspheres prepared by suspension-enhanced dispersion by supercritical CO_2

The in vitro and in vivo anti-tumor efficacy of methotrexate-loaded Fe3O4-poly-L-lactide-poly(ethylene glycol)-poly-L-lactide magnetic composite microspheres(MTX-Fe3O4-PLLA-PEG-PLLA MCMs,MMCMs),which were produced by co-precipitation(C)and microencapsulation(M)in a supercritical process,was evaluated at various levels:cellular,molecular,and integrated.The results at the cellular level indicate that MMCMs(M)show a better anti-proliferation activity than raw MTX and could induce morphological changes of cells undergoing apoptosis.At the molecular level,MMCMs(M)lead to a significantly higher relative mRNA expression of bax/bcl-2 and caspase-3 than MMCMs(C)at 10μg mL-1(P<0.01);and the pro-caspase-3protein expression measured by Western blot analysis also demonstrates that MMCMs(M)can effectively activate pro-caspase-3.At the integrated level,mice bearing a sarcoma-180 tumor are used;in vivo anti-tumor activity tests reveal that MMCMs(M)with magnetic induction display a much higher tumor suppression rate and lower toxicity than raw MTX.Pharmacokinetic studies show that MMCMs(M)with magnetic induction significantly increase the accumulation of MTX in the tumor tissue compared with the other treatments.These results suggest that the MMCMs(M)prepared by the SpEDS process have great potential to play a positive role in the magnetic targeted therapy field.

3D bioprinting of conductive hydrogel for enhanced myogenic differentiation

Recently,hydrogels have gained enormous interest in three-dimensional(3D)bioprinting toward developing functional substitutes for tissue remolding.However,it is highly challenging to transmit electrical signals to cells due to the limited electrical conductivity of the bioprinted hydrogels.Herein,we demonstrate the 3D bioprinting-assisted fabrication of a conductive hydrogel scaffold based on poly-3,4-ethylene dioxythiophene(PEDOT)nanoparticles(NPs)deposited in gelatin methacryloyl(GelMA)for enhanced myogenic differentiation of mouse myoblasts(C2C12 cells).Initially,PEDOT NPs are dispersed in the hydrogel uniformly to enhance the conductive property of the hydrogel scaffold.Notably,the incorporated PEDOT NPs showed minimal influence on the printing ability of GelMA.Then,C2C12 cells are successfully encapsulated within GelMA/PEDOT conductive hydrogels using 3D extrusion bioprinting.Furthermore,the proliferation,migration and differentiation efficacies of C2C12 cells in the highly conductive GelMA/PEDOT composite scaffolds are demonstrated using various in vitro investigations of live/dead staining,F-actin staining,desmin and myogenin immunofluorescence staining.Finally,the effects of electrical signals on the stimulation of the scaffolds are investigated toward the myogenic differentiation of C2C12 cells and the formation of myotubes in vitro.Collectively,our findings demonstrate that the fabrication of the conductive hydrogels provides a feasible approach for the encapsulation of cells and the regeneration of the muscle tissue.

Immune-regulating camouflaged nanoplatforms:A promising strategy to improve cancer nano-immunotherapy

Although nano-immunotherapy has advanced dramatically in recent times,there remain two significant hurdles related to immune systems in cancer treatment,such as(namely)inevitable immune elimination of nanoplat-forms and severely immunosuppressive microenvironment with low immunogenicity,hampering the perfor-mance of nanomedicines.To address these issues,several immune-regulating camouflaged nanocomposites have emerged as prevailing strategies due to their unique characteristics and specific functionalities.In this review,we emphasize the composition,performances,and mechanisms of various immune-regulating camouflaged nano-platforms,including polymer-coated,cell membrane-camouflaged,and exosome-based nanoplatforms to evade the immune clearance of nanoplatforms or upregulate the immune function against the tumor.Further,we discuss the applications of these immune-regulating camouflaged nanoplatforms in directly boosting cancer immunotherapy and some immunogenic cell death-inducing immunotherapeutic modalities,such as chemo-therapy,photothermal therapy,and reactive oxygen species-mediated immunotherapies,highlighting the cur-rent progress and recent advancements.Finally,we conclude the article with interesting perspectives,suggesting future tendencies of these innovative camouflaged constructs towards their translation pipeline.

Synergistic chemo-/photothermal therapy based on supercritical technology-assisted chitosan–indocyanine green/luteolin nanocomposites for wound healing

Despite the success,it is highly challenging to battle against pathogenic biofilms-based chronic bacterial infections by conventional antibiotic therapy.Herein,we report a near-infrared(NIR)/acid-induced nanoplatform based on chitosan(CS)-coated indocyanine green(ICG,photosensitizer)/luteolin(LUT,a natural quorum sensing inhibitor)nanocomposites(ICG/LUT-CS)as antibacterial and antibiofilm agents for skin wound healing.Initially,the ICG/LUT nanoplatforms are prepared by the supercritical antisolvent technology and coated with the CS layer.The obtained ICG/LUT-CS with ultra-high encapsulation efficiency exhibited more favorable photothermal conversion effects and improved NIR laser/acid dual-induced drug release behavior than individual modalities,achieving exceptional bacteria-killing and biofilm elimination effects.Moreover,the ICG/LUT-CS realized the synergetic effects of chemotherapy and photothermal therapy outcomes for wound healing.Together,our findings provided an appealing strategy for the rapid preparation and future translational application of ICG/LUT-CS as an ideal agent for fighting against biofilm infections.