Porous Silicon Carrier Endowed with Photothermal and Therapeutic Effects for Synergistic Wound Disinfection

Duan, Wei; Liu, Xingyue; Zhao, Jingwen; Zheng, Yongke; Wu, Jianmin

doi:10.1021/acsami.2c12012

Cited by 22 publications

(9 citation statements)

References 77 publications

(143 reference statements)

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“…Advanced micro-and nanofabrication techniques enable the fabrication of Si into devices of diverse forms and sizes. As Si has been extensively explored for neural sensing, [45] opto-thermal applications, [46] and optoelectronic stimulation, [47] the integration of functional Si devices with scaffold materials can potentially enable multifunctional devices that can maximize therapeutic outcomes. Overall, this work promotes the development of bioresorbable and conductive neural interfaces to create biomimetic microenvironments that are beneficial for regenerative medicine.…”

Section: Discussionmentioning

confidence: 99%

A Bioresorbable and Conductive Scaffold Integrating Silicon Membranes for Peripheral Nerve Regeneration

Sun,

Guan,

Yang

et al. 2023

Adv Healthcare Materials

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Peripheral nerve injury represents one of the most common types of traumatic damage, severely impairing motor and sensory functions, and posttraumatic nerve regeneration remains a major challenge. Electrical cues are critical bioactive factors that promote nerve regrowth, and bioartificial scaffolds incorporating conductive materials to enhance the endogenous electrical field have been demonstrated to be effective. The utilization of fully biodegradable scaffolds can eliminate material residues, avoid the need for a second surgery and circumvent the need for secondary retrieval procedures. Here, we propose a fully bioresorbable and conductive nerve scaffold integrating N‐type silicon (Si) membranes, which can deliver both structural guidance and electrical cues for the repair of nerve defects. The entire scaffold is fully biodegradable, and the introduction of N‐type Si can significantly promote the proliferation and production of neurotrophic factors in Schwann cells and enhance the calcium activity of dorsal root ganglion (DRG) neurons. The conductive scaffolds enable accelerated nerve regeneration and motor functional recovery in rodents with sciatic nerve transection injuries. This work sheds light on the advancement of bioresorbable and electrically active materials to achieve desirable neural interfaces and improved therapeutic outcomes, offering essential strategies for regenerative medicine.This article is protected by copyright. All rights reserved

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Section: Discussionmentioning

confidence: 99%

A Bioresorbable and Conductive Scaffold Integrating Silicon Membranes for Peripheral Nerve Regeneration

Sun,

Guan,

Yang

et al. 2023

Adv Healthcare Materials

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“…PSi has also been modified to obtain many other unique properties. Surface modification of PSi with polydopamine results in more functional groups on the surface of the material, giving it the ability to produce photothermal effects 117 …”

Section: Nanomaterials and Antimicrobial Treatmentmentioning

confidence: 99%

Applications of nanomaterials as treatments and diagnostic biosensors in microbial infections

Zou,

Tao,

et al. 2023

MedComm – Biomaterials and Applications

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Microbial infection is a major medical problem that seriously threatens public health. The abuse of antibiotics that help evolve the emergence of new drug‐resistance mechanisms has led to the wide‐spread and fast expansion of drug‐resistant bacteria, ultimately evolving into superbugs. This significantly impairs the timely and effective treatment of infections, thus threatening global human well‐being. Not all are pessimistic. Nanomaterials have emerged as an innovative choice. Due to their unique physical and chemical properties, superior bactericidal effects, and high biocompatibility, nanomaterials may help eradicate drug‐resistant bacteria to achieve complete remission of infectious diseases. As biological materials, nanomaterials can also improve the efficacy of existing drugs and treatments and even facilitate diagnostic efficiency. In this review, we aim to comprehensively summarize the antibacterial properties of different kinds of nanomaterials and their applications in other spheres related to treating infectious diseases (targeted therapy, phototherapy, vaccine development, and microbial diagnosis). We highlight the latest advances of nanomaterials in treating infectious diseases in different body systems. Finally, we conclude by discussing the weaknesses of currently available materials and unresolved scientific problems, which may provide insights into the development of approved agents that adequately overcome the notorious drug resistance and thereby provide unprecedented discoveries to improve treatments of the most severe bacterial infections.

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“…Photothermal therapy (PTT), which involves the use of suitable photothermal agents to convert laser energy into heat, has been well developed due to its noninvasive, remotely controllable, tissue-penetrating specificities, and minimal side-effects. − For example, heavy-atom-structured hypoxia-responsive probes for precise photoacoustic imaging and cancer therapy have been developed . In addition, heptacyanine nanodiagnostics with catalase-like activity can be used for synergistic phototherapy of cancer .…”

Section: Introductionmentioning

confidence: 99%

Self-Assembled Nanoflowers Realizes Synergistic Sterilization with Photothermal and Chemical Kinetics Therapy

Wu,

Xiang,

Zhang

et al. 2024

Langmuir

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Wounds caused by bacterial infections have become a major challenge in the medical field; however, the overuse of antibiotics has led to increased resistance and bioaccumulation. Therefore, it is urgent to develop an antibacterial agent with excellent antibacterial properties and biosafety. Here, we designed an antibacterial platform that combines photothermal and chemical kinetics therapies. Platinum−cobalt (PtCo) bimetallic nanoparticles (NPs) were first prepared, and then PtCo@MnO 2 nanoflowers were obtained by adding MES buffer solution and KMnO 4 to the PtCo bimetallic nanoparticle suspension using ultrasound. When light strikes metal NPs, they can strongly absorb the photon energy, resulting in photothermal properties. In addition, Pt and Co were used as the oxidase mimics, and MnO 2 was used as the catalase mimic. In summary, the photothermal capacity of PtCo@MnO 2 nanoflowers with rough surfaces can effectively disrupt the permeability of the bacterial cell membranes. Further, by catalyzing H 2 O 2 , PtCo@MnO 2 nanoflowers can generate large amounts of hydroxyl free radicals, which can damage bacterial cell membranes, proteins, and DNA. In addition, MnO 2 can effectively alleviate the hypoxic environment of the bacterially infected areas and activate deep bacteria, thus achieving the goal of complete sterilization. The in vitro and in vivo results showed that PtCo@MnO 2 displayed excellent antibacterial properties and good biocompatibility.

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Porous Silicon Carrier Endowed with Photothermal and Therapeutic Effects for Synergistic Wound Disinfection

Cited by 22 publications

References 77 publications

A Bioresorbable and Conductive Scaffold Integrating Silicon Membranes for Peripheral Nerve Regeneration

A Bioresorbable and Conductive Scaffold Integrating Silicon Membranes for Peripheral Nerve Regeneration

Applications of nanomaterials as treatments and diagnostic biosensors in microbial infections

Self-Assembled Nanoflowers Realizes Synergistic Sterilization with Photothermal and Chemical Kinetics Therapy

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