Pollen‐Inspired Adhesive Multilobe Microparticles from Microfluidics for Intestinal Drug Delivery

Huang, Dongzhou; Wang, Jinglin; Nie, Min; Chen, Guopu; Zhao, Yuanjin

doi:10.1002/adma.202301192

Cited by 19 publications

(11 citation statements)

References 35 publications

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“…Natural polymeric materials commonly employed in DDSs include gelatin, 69 sodium alginate, 70 chitosan, 71 carboxymethyl cellulose, 72 etc . They generally exhibit excellent biocompatibility, biodegradability and ease of combination with bioactive molecules.…”

Section: Applicable Hydrogel Materials For Ddssmentioning

confidence: 99%

Advancements in hydrogel-based drug delivery systems for the treatment of inflammatory bowel disease: a review

Liu,

Huang,

et al. 2024

Biomater. Sci.

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Section: Applicable Hydrogel Materials For Ddssmentioning

confidence: 99%

Advancements in hydrogel-based drug delivery systems for the treatment of inflammatory bowel disease: a review

Liu,

Huang,

et al. 2024

Biomater. Sci.

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“…In addition to the whole cells for the synthesis of bio-hybrid magnetic robots, other components derived from the plants are also used, and pollen is the most representative example. Pollen serves as a natural micro-carrier for the transfer of cellular content within plants' reproductive organs [82][83][84]. With a wide range of shapes and sizes, pollen grains of the same species exhibit characteristic features, including uniformity in size, dispersity, and shape.…”

Section: Pollenmentioning

confidence: 99%

Bio-Hybrid Magnetic Robots: From Bioengineering to Targeted Therapy

Zhang,

Zeng,

Zhao

et al. 2024

Bioengineering

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Magnetic robots possess an innate ability to navigate through hard-to-reach cavities in the human body, making them promising tools for diagnosing and treating diseases minimally invasively. Despite significant advances, the development of robots with desirable locomotion and full biocompatibility under harsh physiological conditions remains challenging, which put forward new requirements for magnetic robots’ design and material synthesis. Compared to robots that are synthesized with inorganic materials, natural organisms like cells, bacteria or other microalgae exhibit ideal properties for in vivo applications, such as biocompatibility, deformability, auto-fluorescence, and self-propulsion, as well as easy for functional therapeutics engineering. In the process, these organisms can provide autonomous propulsion in biological fluids or external magnetic fields, while retaining their functionalities with integrating artificial robots, thus aiding targeted therapeutic delivery. This kind of robotics is named bio-hybrid magnetic robotics, and in this mini-review, recent progress including their design, engineering and potential for therapeutics delivery will be discussed. Additionally, the historical context and prominent examples will be introduced, and the complexities, potential pitfalls, and opportunities associated with bio-hybrid magnetic robotics will be discussed.

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“…For instance, according to previous studies, carriers' geometries affect a number of processes involved in the drug delivery mechanism. In particular, the geometry of the carrier can affect particle transportation, accumulation, and biodistribution [1] on a vascular level, as well as the rate of internalization, [2][3][4] adhesion, [5] and toxicity. [6] Chemical anisotropy provides a platform for side-specific functionalization [7,8] and/or multi-compartmental encapsulation [9] of several biologically active substances in one capsule.…”

Section: Introduction: What We Can Learn From Naturementioning

confidence: 99%

“…Huang showed pollen-inspired particles for gastrointestinal drug delivery with adhesive multilobe structures made using microfluidics (Figure 1b). [5] Due to its huge surface-bearing capacity, filamentous viruses and phage-mimetic nanoparticles are attracting more and more attention as a drug delivery vehicle Figure 1. A) SEM image of RBC-shaped chitosan microparticles.…”

Section: Introduction: What We Can Learn From Naturementioning

confidence: 99%

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Features of Anisotropic Drug Delivery Systems

Kudryavtseva,

Sukhorukov

2024

Advanced Materials

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Natural materials are anisotropic. Delivery systems occurring in nature, such as viruses, blood cells, pollen, and many others, do have anisotropy, while delivery systems made artificially are mostly isotropic. There is apparent complexity in engineering anisotropic particles or capsules with micron and submicron sizes. Nevertheless, some promising examples of how to fabricate particles with anisotropic shapes or having anisotropic chemical and/or physical properties have been developed. Anisotropy of particles, once they face biological systems, influences their behaviour. Internalisation by the cells, flow in the bloodstream, biodistribution over organs and tissues, directed release, and toxicity of particles regardless of the same chemistry are all reported to be factors of anisotropy of delivery systems. Here, we review the current methods to introduce anisotropy to particles or capsules, including loading with various therapeutic cargo, variable physical properties primarily by anisotropic magnetic properties, controlling directional motion, and making Janus particles. The advantages of combining different anisotropy in one entity for delivery and common problems and limitations for fabrication are under discussion.This article is protected by copyright. All rights reserved

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Pollen‐Inspired Adhesive Multilobe Microparticles from Microfluidics for Intestinal Drug Delivery

Cited by 19 publications

References 35 publications

Advancements in hydrogel-based drug delivery systems for the treatment of inflammatory bowel disease: a review

Advancements in hydrogel-based drug delivery systems for the treatment of inflammatory bowel disease: a review

Bio-Hybrid Magnetic Robots: From Bioengineering to Targeted Therapy

Features of Anisotropic Drug Delivery Systems

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