Ai‐Zheng Chen scite author profile

Mesoporous silica nanoparticles (MSNs), one of the important porous materials, have garnered interest owing to their highly attractive physicochemical features and advantageous morphological attributes. They are of particular importance for use in diverse fields including, but not limited to, adsorption, catalysis, and medicine. Despite their intrinsic stable siliceous frameworks, excellent mechanical strength, and optimal morphological attributes, pristine MSNs suffer from poor drug loading efficiency, as well as compatibility and degradability issues for therapeutic, diagnostic, and tissue engineering purposes. Collectively, the desirable and beneficial properties of MSNs have been harnessed by modifying the surface of the siliceous frameworks through incorporating supramolecular assemblies and various metal species, and through incorporating supramolecular assemblies and various metal species and their conjugates. Substantial advancements of these innovative colloidal inorganic nanocontainers drive researchers in promoting them toward innovative applications like stimuli (light/ultrasound/magnetic)‐responsive delivery‐associated therapies with exceptional performance in vivo. Here, a brief overview of the fabrication of siliceous frameworks, along with discussions on the significant advances in engineering of MSNs, is provided. The scope of the advancement in terms of structural and physicochemical attributes and their effects on biomedical applications with a particular focus on recent studies is emphasized. Finally, interesting perspectives are recapitulated, along with the scope toward clinical translation.

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Supercritical Fluid Technology: An Emphasis on Drug Delivery and Related Biomedical Applications

Kankala

Zhang

Wang

et al. 2017

Adv Healthcare Materials

233

184

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During the past few decades, supercritical fluid (SCF) has emerged as an effective alternative for many traditional pharmaceutical manufacturing processes. Operating active pharmaceutical ingredients (APIs) alone or in combination with various biodegradable polymeric carriers in high-pressure conditions provides enhanced features with respect to their physical properties such as bioavailability enhancement, is of relevance to the application of SCF in the pharmaceutical industry. Herein, recent advances in drug delivery systems manufactured using the SCF technology are reviewed. We provide a brief description of the history, principle, and various preparation methods involved in the SCF technology. Next, we aim to give a brief overview, which provides an emphasis and discussion of recent reports using supercritical carbon dioxide (SC-CO2) for fabrication of polymeric carriers, for applications in areas related to drug delivery, tissue engineering, bio-imaging, and other biomedical applications. We finally summarize with perspectives.

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Multi-Organs-on-Chips: Towards Long-Term Biomedical Investigations

et al. 2019

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With advantageous features such as minimizing the cost, time, and sample size requirements, organ-on-a-chip (OOC) systems have garnered enormous interest from researchers for their ability for real-time monitoring of physical parameters by mimicking the in vivo microenvironment and the precise responses of xenobiotics, i.e., drug efficacy and toxicity over conventional two-dimensional (2D) and three-dimensional (3D) cell cultures, as well as animal models. Recent advancements of OOC systems have evidenced the fabrication of ‘multi-organ-on-chip’ (MOC) models, which connect separated organ chambers together to resemble an ideal pharmacokinetic and pharmacodynamic (PK-PD) model for monitoring the complex interactions between multiple organs and the resultant dynamic responses of multiple organs to pharmaceutical compounds. Numerous varieties of MOC systems have been proposed, mainly focusing on the construction of these multi-organ models, while there are only few studies on how to realize continual, automated, and stable testing, which still remains a significant challenge in the development process of MOCs. Herein, this review emphasizes the recent advancements in realizing long-term testing of MOCs to promote their capability for real-time monitoring of multi-organ interactions and chronic cellular reactions more accurately and steadily over the available chip models. Efforts in this field are still ongoing for better performance in the assessment of preclinical attributes for a new chemical entity. Further, we give a brief overview on the various biomedical applications of long-term testing in MOCs, including several proposed applications and their potential utilization in the future. Finally, we summarize with perspectives.

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Coaxial Extrusion of Tubular Tissue Constructs Using a Gelatin/GelMA Blend Bioink

Wang¹,

Kankala²,

Zhu

et al. 2019

ACS Biomater. Sci. Eng.

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Gelatin methacryloyl (GelMA) hydrogels have been commonly used in fabricating cannular tissue constructs due to their excellent cytocompatibility, as well as amenity to migration and proliferation of encapsulated cells. Here, we present a simple yet efficient approach for fabricating hollow structures with gelatin-based hydrogels using a modified microfluidic-based biofabrication technology. Hollow microfibers were generated using a customized coaxial nozzle by soft templating against a polyvinyl alcohol solution core. Reversible thermo-cross-linking and irreversible photo-cross-linking were achieved successively through gelatin (Gel) mixed into the GelMA solution and by irradiating with UV light, resulting in stable and continuous generation of hollow structures. Furthermore, in vitro evaluations confirmed good proliferation of multiple cell types in the GelMA/Gel hollow microfibers. Together, we believe that this approach holds great potential in engineering cannular constructs for applications in regenerative medicine and tissue modeling.

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Fabrication of arbitrary 3D components in cardiac surgery: from macro-, micro- to nanoscale

Kankala

Zhu

et al. 2017

Biofabrication

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Fabrication of tissue-/organ-like structures at arbitrary geometries by mimicking the properties of the complex material offers enormous interest to the research and clinical applicability in cardiovascular diseases. Patient-specific, durable, and realistic three-dimensional (3D) cardiac models for anatomic consideration have been developed for education, pro-surgery planning, and intra-surgery guidance. In cardiac tissue engineering (TE), 3D printing technology is the most convenient and efficient microfabrication method to create biomimetic cardiovascular tissue for the potential in vivo implantation. Although booming rapidly, this technology is still in its infancy. Herein, we provide an emphasis on the application of this technology in clinical practices, micro- and nanoscale fabrications by cardiac TE. Initially, we will give an overview on the fabrication methods that can be used to synthesize the arbitrary 3D components with controlled features and will subsequently highlight the current limitations and future perspective of 3D printing used for cardiovascular diseases.

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Ai‐Zheng Chen

Nanoarchitectured Structure and Surface Biofunctionality of Mesoporous Silica Nanoparticles

Supercritical Fluid Technology: An Emphasis on Drug Delivery and Related Biomedical Applications

Multi-Organs-on-Chips: Towards Long-Term Biomedical Investigations

Coaxial Extrusion of Tubular Tissue Constructs Using a Gelatin/GelMA Blend Bioink

Fabrication of arbitrary 3D components in cardiac surgery: from macro-, micro- to nanoscale

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