&lt;p&gt;A novel composite scaffold of Cu-doped nano calcium-deficient hydroxyapatite/multi-(amino acid) copolymer for bone tissue regeneration&lt;/p&gt;

Mou, Ping; Peng, Haitao; Zhou, Li; Li, Lin; Li, Hong; Huang, Qiang

doi:10.2147/ijn.s195316

Cited by 21 publications

(17 citation statements)

References 42 publications

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“…At the same time, copper has strong antibacterial properties and is not prone to drug resistance. Copper NPs can play an essential role in inhibiting infection and forming bone matrix by releasing copper ions ( Liu et al, 2019 ; Mou et al, 2019 ; Anitha and Muthukumaran, 2020 ; Lv et al, 2020 ). As a redox metal ( Tripathi and Gaur, 2004 ; Rauf et al, 2019 ), it can catalyze the formation of ROS, and at the same time, can destroy the permeability of bacterial membranes, resulting in the leakage of reducing sugars and proteins from cells.…”

Section: Nanomaterials Loadingmentioning

confidence: 99%

Nano-Modified Titanium Implant Materials: A Way Toward Improved Antibacterial Properties

Liu

Attarilar

et al. 2020

Front. Bioeng. Biotechnol.

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Section: Nanomaterials Loadingmentioning

confidence: 99%

Nano-Modified Titanium Implant Materials: A Way Toward Improved Antibacterial Properties

Liu

Attarilar

et al. 2020

Front. Bioeng. Biotechnol.

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“…Metal ions are featured with their intrinsic bioactivity for satisfying different biomedical application requirements. [110][111][112][113][114][115][116][117][118] For instance, Ca 2+ ions are the important component of bone, signifying that CaO 2 nanoparticles might be applicable for tissue engineering. [119,120] Based on the consideration that CaO 2 nanoparticles are typically designed for tumor-therapeutic purposes, we recently loaded CaO 2 nanoparticles into the matrix of 3D printing akermanite scaffold with the simultaneously integrated magnetic Fe 3 O 4 nanoparticles (designated as AKT-Fe 3 O 4 -CaO 2 ), which exerted the specific functionality for osteosarcoma treatment (Figure 10).…”

Section: Metal Peroxide Nanoparticles For Tissue Regenerationmentioning

confidence: 99%

Chemoreactive Nanotherapeutics by Metal Peroxide Based Nanomedicine

Qian

et al. 2020

Advanced Science

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The advances of nanobiotechnology and nanomedicine enable the triggering of in situ chemical reactions in disease microenvironment for achieving disease-specific nanotherapeutics with both intriguing therapeutic efficacy and mitigated side effects. Metal peroxide based nanoparticles, as one of the important but generally ignored categories of metal-involved nanosystems, can function as the solid precursors to produce oxygen (O 2 ) and hydrogen peroxide (H 2 O 2 ) through simple chemical reactions, both of which are the important chemical species for enhancing the therapeutic outcome of versatile modalities, accompanied with the unique bioactivity of metal ion based components. This progress report summarizes and discusses the most representative paradigms of metal peroxides in chemoreactive nanomedicine, including copper peroxide (CuO 2 ), calcium peroxide (CaO 2 ), magnesium peroxide (MgO 2 ), zinc peroxide (ZnO 2 ), barium peroxide (BaO 2 ), and titanium peroxide (TiO x ) nanosystems. Their reactions and corresponding products have been broadly explored in versatile disease treatments, including catalytic nanotherapeutics, photodynamic therapy, radiation therapy, antibacterial infection, tissue regeneration, and some synergistically therapeutic applications. This progress report particularly focuses on the underlying reaction mechanisms on enhancing the therapeutic efficacy of these modalities, accompanied with the discussion on their biological effects and biosafety. The existing gap between fundamental research and clinical translation of these metal peroxide based nanotherapeutic technologies is finally discussed in depth.

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“…However, characteristics of heterogeneous composite scaffolds must be analyzed regarding biodegradation, since the interaction between the implant and the patient’s body takes place on the surface of the implant. The surface of the implant can change during treatment as a result of degradation and subsequent exposure of lower layers [ 2 , 124 , 125 ]. To evaluate biodegradation behavior or implant performance, the model must be carefully selected, particularly as the cell line or animal used can influence the results obtained, especially in in vitro models.…”

Section: Bone Graft Substitutes For the Reconstruction Of Large Bomentioning

confidence: 99%

Challenges in Bone Tissue Regeneration: Stem Cell Therapy, Biofunctionality and Antimicrobial Properties of Novel Materials and Its Evolution

Riester

Borgolte

Csuk

et al. 2020

IJMS

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An aging population leads to increasing demand for sustained quality of life with the aid of novel implants. Patients expect fast healing and few complications after surgery. Increased biofunctionality and antimicrobial behavior of implants, in combination with supportive stem cell therapy, can meet these expectations. Recent research in the field of bone implants and the implementation of autologous mesenchymal stem cells in the treatment of bone defects is outlined and evaluated in this review. The article highlights several advantages, limitations and advances for metal-, ceramic- and polymer-based implants and discusses the future need for high-throughput screening systems used in the evaluation of novel developed materials and stem cell therapies. Automated cell culture systems, microarray assays or microfluidic devices are required to efficiently analyze the increasing number of new materials and stem cell-assisted therapies. Approaches described in the literature to improve biocompatibility, biofunctionality and stem cell differentiation efficiencies of implants range from the design of drug-laden nanoparticles to chemical modification and the selection of materials that mimic the natural tissue. Combining suitable implants with mesenchymal stem cell treatment promises to shorten healing time and increase treatment success. Most research studies focus on creating antibacterial materials or modifying implants with antibacterial coatings in order to address the increasing number of complications after surgeries that are mostly caused by bacterial infections. Moreover, treatment of multiresistant pathogens will pose even bigger challenges in hospitals in the future, according to the World Health Organization (WHO). These antibacterial materials will help to reduce infections after surgery and the number of antibiotic treatments that contribute to the emergence of new multiresistant pathogens, whilst the antibacterial implants will help reduce the amount of antibiotics used in clinical treatment.

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<p>A novel composite scaffold of Cu-doped nano calcium-deficient hydroxyapatite/multi-(amino acid) copolymer for bone tissue regeneration</p>

Cited by 21 publications

References 42 publications

Nano-Modified Titanium Implant Materials: A Way Toward Improved Antibacterial Properties

Nano-Modified Titanium Implant Materials: A Way Toward Improved Antibacterial Properties

Chemoreactive Nanotherapeutics by Metal Peroxide Based Nanomedicine

Challenges in Bone Tissue Regeneration: Stem Cell Therapy, Biofunctionality and Antimicrobial Properties of Novel Materials and Its Evolution

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