The Horizon of the Emulsion Particulate Strategy: Engineering Hollow Particles for Biomedical Applications

Xia, Yufei; Na, Xiangming; Wu, Jie; Ma, Guanghui

doi:10.1002/adma.201801159

Cited by 35 publications

(27 citation statements)

References 167 publications

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“…In addition to the environmental applications described above, emulsion‐templated porous materials have also been widely used in other applications such as heterogeneous catalysis, [ 132 , 152 , 203 , 211 , 220 , 226 , 249 ] biomedical applications, [ 26 , 50 , 161 , 170 ] energy storage, [ 234 , 236 , 241 , 251 , 258 ] and chromatography, [ 111 , 123 ] to name a few. All these applications have explored the highly interconnected hierarchical porosity, chemical functionality and desired physical properties presented by emulsion‐templated porous materials.…”

Section: Discussionmentioning

confidence: 99%

“…This concept of stabilizing interfaces with particles of different shapes and sizes is known as the “Pickering effect” or “Pickering stabilization”, [ 47 ] which has also been used to stabilize O/W, water‐in‐oil (W/O), and non‐aqueous emulsions. [ 48 , 49 , 50 , 51 ] Different types of particles including metal–organic framework (MOF) nanoparticles (NPs) have been used as stabilizers for Pickering emulsions. [ 51 ] For instance, the W/W emulsions have been stabilized with nanoplates and nanorods in the form of cellulose nanocrystals.…”

Section: Introductionmentioning

confidence: 99%

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Fundamentals and Design‐Led Synthesis of Emulsion‐Templated Porous Materials for Environmental Applications

et al. 2021

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Emulsion templating is at the forefront of producing a wide array of porous materials that offers interconnected porous structure, easy permeability, homogeneous flow-through, high diffusion rates, convective mass transfer, and direct accessibility to interact with atoms/ions/molecules throughout the exterior and interior of the bulk. These interesting features together with easily available ingredients, facile preparation methods, flexible pore-size tuning protocols, controlled surface modification strategies, good physicochemical and dimensional stability, lightweight, convenient processing and subsequent recovery, superior pollutants remediation/monitoring performance, and decent recyclability underscore the benchmark potential of the emulsion-templated porous materials in large-scale practical environmental applications. To this end, many research breakthroughs in emulsion templating technique witnessed by the recent achievements have been widely unfolded and currently being extensively explored to address many of the environmental challenges. Taking into account the burgeoning progress of the emulsion-templated porous materials in the environmental field, this review article provides a conceptual overview of emulsions and emulsion templating technique, sums up the general procedures to design and fabricate many state-of-the-art emulsion-templated porous materials, and presents a critical overview of their marked momentum in adsorption, separation, disinfection, catalysis/degradation, capture, and sensing of the inorganic, organic and biological contaminants in water and air.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Fundamentals and Design‐Led Synthesis of Emulsion‐Templated Porous Materials for Environmental Applications

et al. 2021

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“…In the field of tissue engineering, microsphere-type microscaffolds are highlighted due to the flexibility in their compositions and functional designs and as units to construct 3D structures with desired spacial speciality, as well as, their injectability to fill irregular defects at minimal invasion. 36,37 In this study, multipurpose biodegradable microspheres were developed in order to regenerate bone defects in the conditions of the severely infected cases. Apart from antibacterial activity, other functions like antioxidant activity and osteoinductivity are also crucial in determining the efficiency of bone formation.…”

Section: Discussionmentioning

confidence: 99%

Antibacterial, conductive, and osteocompatible polyorganophosphazene microscaffolds for the repair of infectious calvarial defect

Huang

Zheng

et al. 2021

J Biomedical Materials Res

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Many osteoconductive and osteoinductive scaffolds have been developed for promoting bone regeneration; however, failures would occur in osteogenesis when the defect area is significantly infected while the biomaterials have no antibacterial performances. Herein, a kind of multipurpose PATGP@PDA + Ag microspheres was prepared via emulsion method by using a conductive aniline tetramer (AT) substituted polyphosphazene (PATGP), followed by polydopamine (PDA) modification and silver nanoparticles (AgNPs) loading. The PATGP@PDA + Ag microspheres demonstrated a strong antibacterial activity against Staphylococcus aureus both in vitro and in vivo, while showing no cytotoxicity at an optimized AgNPs loading amount. Due to the electron‐donor structure of the AT moieties, the PATGP@PDA + Ag microspheres displayed antioxidant capacities to scavenge reactive oxygen species (ROS). Due to their phosphorus‐rich feature, the PATGP@PDA + Ag microspheres favored the osteogenic differentiation of bone marrow mesenchymal stem cells (BMSCs). As controls, nonconductive microspheres (PAGP@PDA, PAGP@PDA + Ag) were prepared similarly by using poly[(ethylalanine)(ethylglycyl)]phosphazene (PAGP). By co‐implanting these microspheres with S. aureus into rat calvarial defects, among them, it was determined that the PATGP@PDA + Ag microspheres achieved the most abundant neo‐bone formation, benefiting from their antibacterial, antioxidant and osteogenic activities. These results revealed that AgNPs loaded scaffolds made of conductive polyphosphazenes were promising for the regeneration of infected bone defects.

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“…[ 10 , 11 ] As an alternative, emulsion‐based technique is a popular method for porous particle generation, specifically including phase inversion, phase ripening, and phase separation. [ 8 , 12 ] Compared with the template method, this technique does not require removing process, and thus there is no extra etchants or pore‐forming agents needed, which indicates the emulsion‐based procedure is biologically safer to some extent. [ 13 , 14 ] However, the generation devices used in this method always need elaborate design that is not easy‐operating, and the diffusion of organic solvents during the process can also affect the biocompatibility of the generated particles, which might hamper their further applications in biomedicine.…”

Section: Introductionmentioning

confidence: 99%

Nanomotor‐Derived Porous Biomedical Particles from Droplet Microfluidics

et al. 2021

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Porous particles have found widespread applications in therapeutic diagnosis, drug delivery, and tissue engineering due to their typical properties of large surface area, extensive loading capacity, and hierarchical microstructures. Attempts in this aspect are focusing on the development of effective methods to generate functional porous particles. Herein, a simple droplet microfluidics for continuously and directly generating porous particles by introducing bubble-propelled nanomotors into the system is presented. As the nanomotors can continuously generate gas bubbles in the unsolidified droplet templates, the desirable porous microparticles can be obtained after droplet polymerization. It is demonstrated that the generation process is highly controlled and the resultant microparticles show excellent porosity and monodispersity. In addition, the obtained porous microparticles can serve as microcarriers for 3D cell culture, because of their characteristic porous structures and favorable biocompatibility. Moreover, owing to the existence of oxygen in these microparticles, they can be used to improve the healing effects of wounds in the type I diabetes rat models. These remarkable features of the generation strategy and the porous microparticles point to their potential values in various biomedical fields.

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The Horizon of the Emulsion Particulate Strategy: Engineering Hollow Particles for Biomedical Applications

Cited by 35 publications

References 167 publications

Fundamentals and Design‐Led Synthesis of Emulsion‐Templated Porous Materials for Environmental Applications

Fundamentals and Design‐Led Synthesis of Emulsion‐Templated Porous Materials for Environmental Applications

Antibacterial, conductive, and osteocompatible polyorganophosphazene microscaffolds for the repair of infectious calvarial defect

Nanomotor‐Derived Porous Biomedical Particles from Droplet Microfluidics

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