Injectable Functional Biomaterials for Minimally Invasive Surgery

Microspheres applied in medical applications experience explosive development in recent years, such as drug release, cell culture, and bone tissue engineering, etc. However, there are still some bottlenecks both in economy and technology lay that cannot be ignored. For instance, microsphere technology has not been used in cell culture widely because of its uneconomical cost; as the core of drug‐loaded microsphere, targeted microsphere technology is still not mature enough. Besides, the common microsphere fabrication methods: microfluidic or emulsion technology is difficult to guarantee high biocompatibility of microsphere due to utilization of photoinitiator, crosslinking agent, surfactant, and other substances. Therefore, gas‐shearing technology has been proposed to solve these above shortcomings successfully. This paper focuses more on heteromorphic microspheres rather than on single microspheres which begins with a minute introduction of microsphere preparation methods: microfluidic, coaxial electrospray, emulsion, and gas‐shearing technology. Then its medical applications: drug release, cell culture, bone tissue engineering, and hemostasis are discussed in detail. The disadvantages of fabrication methods and bottlenecks for medical applications at present are also stated. At the end, perspectives of microsphere development are put forward.

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“…Therefore, microsphere is a superb material with great potential in the field of hemostasis in vitro. [ 124,125 ]…”

Section: Medical Applicationsmentioning

confidence: 99%

Preparation of Single, Heteromorphic Microspheres, and Their Progress for Medical Applications

Zhang

Wang

et al. 2020

Macro Materials & Eng

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“…This property is also crucial for more precise implantation and site-specific drug delivery into poorly reachable tissue sites and interface tissues, where wound healing takes a long time. Injectable hydrogels [8] can be generated in situ by using chemically and/or physically crosslinking hydrogels; thus they can be delivered into the body or a targeted site of a tissue through a catheter or by a syringe. Injectable hydrogels are particularly attractive biomaterials for use in soft tissues such as the brain and spinal cord, [9,10] since they have viscoelastic and unique rheological properties that can mimic the mechanical characteristics of soft tissues.…”

Section: Introductionmentioning

confidence: 99%

Recent Advances in Injectable Hydrogels for Controlled and Local Drug Delivery

Rizzo

Kehr

2020

Adv Healthcare Materials

199

152

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Injectable hydrogels have received considerable interest in the biomedical field due to their potential applications in minimally invasive local drug delivery, more precise implantation, and site‐specific drug delivery into poorly reachable tissue sites and into interface tissues, where wound healing takes a long time. Injectable hydrogels, such as in situ forming and/or shear‐thinning hydrogels, can be generated using chemically and/or physically crosslinked hydrogels. Yet, for controlled and local drug delivery applications, the ideal injectable hydrogel should be able to provide controlled and sustained release of drug molecules to the target site when needed and should limit nonspecific drug molecule distribution in healthy tissues. Thus, such hydrogels should sense the environmental changes that arise in disease states and be able to release the optimal amount of drug over the necessary time period to the target region. To address this, researchers have designed stimuli‐responsive injectable hydrogels. Stimuli‐responsive hydrogels change their shape or volume when they sense environmental stimuli, e.g., pH, temperature, light, electrical signals, or enzymatic changes, and deliver an optimal concentration of drugs to the target site without affecting healthy tissues.

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“…[1][2][3] Owing to the transient nature of physical bonds between chains (that associate and dissociate being driven by external stimuli), these gels demonstrate high strength, 4 exceptional stretchability, 5 high fracture toughness 6 and fatigue resistance, 7 and rapid self-recovery. 8 Among other important features of supramolecular gels, it is worth mentioning (i) their self-healing ability, 9,10 (ii) shape memory property, 11,12 (iii) self-assembling (the ability to undergo sol-gel-sol transitions driven by mechanical and chemical triggers), 13,14 and (iv) the ability to secure strong and robust adhesion to a variety of surfaces. [15][16][17] As the mechanical behavior of supramolecular gels is strongly affected by rearrangement (dissociation and re-association) of temporary bonds between chains, a number of studies analyzed the kinetics of this process by means of the standard rheological tests (shear oscillations in the frequency sweep mode).…”

Section: Introductionmentioning

confidence: 99%