“Motile-targeting” drug delivery platforms based on micro/nanorobots for tumor therapy

Zhang, Di; Liu, Shuyi; Guan, Jianguo; Mou, Fangzhi

doi:10.3389/fbioe.2022.1002171

Cited by 18 publications

(22 citation statements)

References 169 publications

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“…198 Given that, immunomodulatory approaches using micro/ nanorobots (MNRs) hold great promise for the treatment of PC in the future outlook. 199 They can be designed to deliver nanoparticles that can target and modulate the immune response in the TME. These nanoparticles can be loaded with therapeutic agents, such as cytokines or ICIs, that can stimulate the immune system to recognize and attack cancer cells.…”

Section: Nanoparticle-based Immunogenic Cellmentioning

confidence: 99%

“…For instance, they can be designed to target the stromal cells in the pancreatic TME, which are known to play a critical role in promoting tumor growth and suppressing the immune response. 199 proaches using micro/nanorobots holds great promise for the treatment of PC and other types of cancer. In this regard, Song X et al study introduces drug-loaded magnetic microrobots that can induce macrophages to exhibit the antitumor phenotype, which helps target and suppress cancer cells (Figure 8D).…”

Section: Nanoparticle-based Immunogenic Cellmentioning

confidence: 99%

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Advancing Cancer Treatment Through Nanotechnology Driven Immunotherapy for Pancreatic Cancer

Kamalasanan,

et al. 2023

ACS Appl. Nano Mater.

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Pancreatic cancer is expected to be the most lethal cancer by 2030; among that, PDAC is the most prominent one, which is immune resistant, posing substantial hurdles to creating effective therapeutics. Despite the advancements in immunotherapy, its application in PDAC is less successful. Uniquely, PDAC tumors are “cold” to immune response mainly due to suppression of spatiotemporal immune signatures from cells and tumor microenvironment. Contrary to other immune-responsive tumors, immunotherapy in combination with chemotherapy in PDAC, is still diffusion-limiting to the drugs and less cytotoxic to cancer cells. Moreover, newer approaches exploring nanotechnology are being tried to make PDAC “hot” and immunogenic in nature and are promising. This review analyses the design strategies of nanosystems for effective spatiotemporal signaling to improve immune response to PDAC tumors. Particularly, that helps to overcome early evasion in phase I, and resistance to the antitumor immune response by modulating cellular and tumor microenvironment (TME) through the latest advancements in nanotechnology, immune mechanisms, and potential delivery routes for PDAC treatment. Ongoing and completed clinical trials of nanotechnology-driven immunotherapies in pancreatic cancer are also highlighted here. Overall, this approach of nanotechnological strategy to enhance immunotherapy in PDAC holds great promise and may contribute to a groundbreaking shift in the therapeutic management of PDAC and reduce the mortality rate of this lethal disease.

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Section: Nanoparticle-based Immunogenic Cellmentioning

confidence: 99%

Section: Nanoparticle-based Immunogenic Cellmentioning

confidence: 99%

Advancing Cancer Treatment Through Nanotechnology Driven Immunotherapy for Pancreatic Cancer

Kamalasanan,

et al. 2023

ACS Appl. Nano Mater.

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“…Motile micro/nanorobots (MNRs) are capable of propelling and navigating in various liquid media, and have been envisioned to provide revolutionary technological advances for drug delivery, microsurgeries, and micro/nanoengineering 20–29 . In terms of energy sources, MNRs can be categorized as biohybrid MNRs, 30–33 chemically powered MNRs, 34–36 and those powered by external fields, such as light, ultrasound, electric field, and magnetic field 37–41 .…”

Section: Introductionmentioning

confidence: 99%

Swarming magnetic photonic‐crystal microrobots with on‐the‐fly visual pH detection and self‐regulated drug delivery

Zheng

Mou

et al. 2023

InfoMat

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Swarming magnetic micro/nanorobots hold great promise for biomedical applications, but at present suffer from inferior capabilities to perceive and respond to chemical signals in local microenvironments. Here we demonstrate swarming magnetic photonic‐crystal microrobots (PC‐bots) capable of spontaneously performing on‐the‐fly visual pH detection and self‐regulated drug delivery by perceiving local pH changes. The magnetic PC‐bots consist of pH‐responsive hydrogel microspheres with encapsulated one‐dimensional periodic assemblies of Fe3O4 nanoparticles. By programming external rotating magnetic fields, they can self‐organize into large swarms with much‐enhanced collective velocity to actively find targets while shining bright “blinking” structural colors. When approaching the target with abnormal pH conditions (e.g., an ulcerated superficial tumor lesion), the PC‐bots can visualize local pH changes on the fly via pH‐responsive structural colors, and realize self‐regulated release of the loaded drugs by recognizing local pH. This work facilitates the development of intelligent micro/nanorobots for active “motile‐targeting” tumor diagnosis and treatment.image

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“…Over long evolutionary periods, nature has selected the optimal locomotion strategies for single-cell organisms to survive, such as the cilia of Paramecium, [1] the flagella of Chlamydomonas, [2,3] stimuli, including light, [13][14][15] acoustics, [16] electricity, [17][18][19] heat, [20] and magnetic fields, [21][22][23][24][25] have fascinated robotics scientists with their wide range of applications, such as environmental remediation, [26] chemical reactions, [27,28] bioassays, [29,30] and biomedicine. [31][32][33][34] Magnetic actuation strategy is a promising choice for the construction of pseudopod robots due to its advantages of easy access, biosecurity and ease of programming. [35][36][37][38] Nevertheless, it remains a challenge to emulate the high environmental adaptability and enhanced task capabilities of natural amoeba or amoeboid cells.…”

Section: Introductionmentioning

confidence: 99%

Amoeba‐Inspired Magnetic Venom Microrobots

Zhang

Deng

Zhao

et al. 2023

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Nature provides a successful evolutionary direction for single‐celled organisms to solve complex problems and complete survival tasks – pseudopodium. Amoeba, a unicellular protozoan, can produce temporary pseudopods in any direction by controlling the directional flow of protoplasm to perform important life activities such as environmental sensing, motility, predation, and excretion. However, creating robotic systems with pseudopodia to emulate environmental adaptability and tasking capabilities of natural amoeba or amoeboid cells remains challenging. Here, this work presents a strategy that uses alternating magnetic fields to reconfigure magnetic droplet into Amoeba‐like microrobot, and the mechanisms of pseudopodia generation and locomotion are analyzed. By simply adjusting the field direction, microrobots switch in monopodia, bipodia, and locomotion modes, performing all pseudopod operations such as active contraction, extension, bending, and amoeboid movement. The pseudopodia endow droplet robots with excellent maneuverability to adapt to environmental variations, including spanning 3D terrains and swimming in bulk liquids. Inspired by the “Venom,” the phagocytosis and parasitic behaviors have also been investigated. Parasitic droplets inherit all the capabilities of amoeboid robot, expanding their applicable scenarios such as reagent analysis, microchemical reactions, calculi removal, and drug‐mediated thrombolysis. This microrobot may provide fundamental understanding of single‐celled livings, and potential applications in biotechnology and biomedicine.

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“Motile-targeting” drug delivery platforms based on micro/nanorobots for tumor therapy

Cited by 18 publications

References 169 publications

Advancing Cancer Treatment Through Nanotechnology Driven Immunotherapy for Pancreatic Cancer

Advancing Cancer Treatment Through Nanotechnology Driven Immunotherapy for Pancreatic Cancer

Swarming magnetic photonic‐crystal microrobots with on‐the‐fly visual pH detection and self‐regulated drug delivery

Amoeba‐Inspired Magnetic Venom Microrobots

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