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Author: search.filters.author.Ali Mohammad AmaniLanguage: search.filters.language.English

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    Alginate hydrogel film reinforced with Fe3O4@SiO2/Schiff-base/Cu(II) nanoparticles in promoting diabetic wound healing
    (Elsevier BV, 2026-04)
    Sedigheh Azadi
    ;
    Alireza Abbaspour
    ;
    Seyed Reza Kasaee
    ;
    Farhad Koohpeyma
    ;
    Esmat Azizipour
    In the quest to enhance diabetic wound healing, we synthesized Fe3O4@SiO2/Schiff-base complex of Cu(II) magnetic nanoparticles (MNPs) embedded in sodium alginate hydrogel. This study analyzed the effects of 1% and 10% Cu(II) nanoparticles (NPs) concentrations on wound closure and tissue regeneration in a diabetic rat model. Streptozotocin-induced diabetic Sprague-Dawley rats were used to evaluate the in vivo efficacy of NPs. Characterization involved digital photography for wound closure quantification, histopathological analysis for tissue repair assessment, and statistical methods for data interpretation. Our findings indicated that the 1% Cu nanoparticle (NP) -embedded hydrogel significantly improved wound healing, including enhanced reepithelialization, collagen deposition, neovascularization, granulation tissue formation, and fibroblast activation, while also reducing inflammation. The 10% Cu NP formulation did not demonstrate the same level of efficacy, suggesting a concentration-dependent therapeutic window for copper ion release. This novel NP hydrogel showcases the potential of copper-based NPs in diabetic wound management, offering a cost-effective and promising approach for treating a global health issue.
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    A comprehensive review on MXene nanostructures for biosensing, imaging, and therapeutic systems
    (Elsevier BV, 2026-02)
    Ali Mohammad Amani
    ;
    Ehsan Vafa
    ;
    Maryam Mirzae
    ;
    Milad Abbasi
    ;
    Ahmad Vaez
    Because of their exceptional electrical, mechanical, dimensional, chemical, and magnetic characteristics, MXenes have attracted an abundance of interest in scholarly study lately. According to recent developments and discoveries, MXene, a multilayered compound with a two-dimensional (2D) framework, has a lot greater promise for use in bioengineering and medical research than other nanosystems. These uses encompass medical procedures, administering medications, biosensor technologies, incorporation, antimicrobial agents, and biological imaging. MXenes are very attractive prospects for therapeutic, diagnostic, and theranostic use because of their distinctive features, which include their substantial conductivity to electricity, magnetic luminescence, wide extent of coverage, excellent biocompatibility, and low toxicological profile. Modifications to the MXene surfaces are biocompatible and serve a variety of purposes, such as directing ligands to certain locations for preferred aggregation, which makes them suitable for use in particular applications. A description of the properties, changes, and synthesis techniques of MXene nanostructures is presented in this work. The practical applications of MXene-derived nanostructures in biomedical fields are also thoroughly evaluated in this study, with an emphasis on implants, biosensing, biological imaging, antibacterial activities, and versatile therapeutic systems. The potential opportunities and difficulties related to the use of MXenes throughout the field of biological medicine are also covered in this paper.
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    Effect of Bioactive Glass on PXDDA - PXDDA-co-PLA Nanocomposite for Hard Tissue Reconstruction: Synthesis and Characterization
    (Elsevier BV, 2025-05)
    Ehsan Vafa
    ;
    Lobat Tayebi
    ;
    Fatemeh Azizli
    ;
    Somayeh Parham
    ;
    Katayoon Rezaeeparto
    Newer bone graft materials face various challenges in achieving optimal mechanical strength, bioactivity, and antibacterial action simultaneously, which can result in suboptimal regeneration outcomes and increased infection risks In the present study, we developed a novel nanocomposite of poly (xylitol- co -dodecanedioic acid) (PXDDA) and poly (lactic acid) (PLA) with 1–10 wt% incorporation of bioactive glass (BG), utilizing a a PXDDA-co-PLA compatibilizer for maintaining homogeneity. Extensive characterization techniques including, Fourier infrared spectroscopy (FTIR), X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), Brunauere Emmette Teller (BET), Proton Nuclear Magnetic Resonance (1H NMR) and contact angle measurements, revealed that the addition of BG imparted a microporous, rough surface morphology (with a contact angle of 55–60°), ideal for cell attachment. Mechanical testing demonstrated a significant enhancement with 10 wt% BG, increasing tensile strength by approximately 120 % while reducing elongation. In vitro bioactivity tests indicated that hydroxyapatite deposition depended on BG concentration, reaching a maximum of 96.7 % surface coverage at 10 wt% BG. Antibacterial action against Staphylococcus aureus and Escherichia coli confirmed substantial inhibition (approximately 85 % decrease), with saturation occurring at 7 wt% BG. With tunable mechanical properties, enhanced biomineralization, and intrinsic antibacterial capacity, this nanocomposite overcomes the significant limitations of existing bone grafts, providing a clinically viable load-bearing alternative.
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    MXenes in tissue engineering and regenerative medicine: Advances, challenges, and future perspectives
    (Elsevier BV, 2025-10)
    Ali Mohammad Amani
    ;
    Lobat Tayebi
    ;
    Ehsan Vafa
    ;
    Mohammad Javad Azizli
    ;
    Milad Abbasi
    The appealing charm of two-dimensional (2D) materials has sparked a wave of innovation across diverse scientific domains, particularly in the realm of biomedical and therapeutic applications. Among these remarkable materials, MXenes stand out as transition metal nitrides and carbides endowed with extraordinary properties. Boasting low toxicity, expansive surface area, antibacterial prowess, biocompatibility, hydrophilicity, and impressive electrical conductivity, MXenes hold immense promise for a myriad of biomedical applications from bioimaging to cancer therapy and beyond. Despite their vast potential, challenges persist in ensuring controlled drug release, stability in physiological milieus, and biodegradability. By harnessing the transformative power of nanomedicine, meticulously crafted MXene ultra-thin nanosheets emerge as versatile inorganic nanosystems primed for diverse biomedical roles. Positioned as optimal candidates for regenerative medicine and tissue engineering, MXenes mark a new age of healthcare innovation. This article delves into the latest strides made in leveraging 2D MXenes for cutting-edge regenerative medicine and tissue engineering applications while shedding light on the formidable obstacles and promising future vistas awaiting exploration with these extraordinary materials.
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    Exploring the revolutionary potential of MXene nanoparticles in breast Cancer therapy: A review of applications and future prospects
    (Elsevier BV, 2025-04)
    Ali Mohammad Amani
    ;
    Lobat Tayebi
    ;
    Ehsan Vafa
    ;
    Reza Bazargan-Lari
    ;
    Milad Abbasi
    Breast cancer is a leading cause of cancer-related deaths in women worldwide. Early detection and accurate diagnosis are crucial for successful treatment and improving patient outcomes. Nanoparticles, such as MXenes, have emerged as a promising tool for various breast cancer applications due to their unique properties. MXenes possess a high surface area and excellent biocompatibility, and can be engineered to enhance targeting ability, as well as mechanical, electrochemical, and optical properties. This review article explores the potential of MXenes in breast cancer detection and treatment, including miRNA detection, MRI-guided photothermal therapy, combined therapy, and immunotherapy. MXenes can be used for miRNA detection, which has shown promise as a biomarker for breast cancer. MXenes can also be used for MRI-guided photothermal therapy, where they can absorb light and convert it into heat to destroy cancer cells. Additionally, MXenes can be used in combination therapy with other drugs to enhance their efficacy. MXenes can also be used for immunotherapy by enhancing the immune response against cancer cells. The article also discusses the future prospects of MXenes in breast cancer research and their cytotoxicity effects. The use of MXenes in breast cancer research is a novel approach with great potential for improving patient outcomes.
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    Mxenes as a versatile nanoplatform: Synthesis and emerging biomedical applications
    (Elsevier BV, 2025-09-25)
    Ali Mohammad Amani
    ;
    Ehsan Vafa
    ;
    Maryam Mirzae
    ;
    Milad Abbasi
    ;
    Ahmad Vaez
    Recently, MXenes have garnered significant attention in academic research due to their remarkable structural, electrical, magnetic, optical, mechanical, and chemical properties. New advancements and emerging findings indicate that MXene, classified as a two-dimensional (2D) layered material, exhibits significantly more potential in the field of biomedicine and biotechnology compared to existing nanosystems. These applications include acting as antibacterial agents, biosensor systems, the delivery and loading of drugs, bioimaging, and therapeutic interventions. The unique characteristics of MXenes, such as their significant electrical conductivity, large surface area, low toxicity, magnetism, luminescence, and high biocompatibility, make them highly promising candidates for diagnostic, therapeutic, and theranostic applications. Surface modifications of MXenes exhibit biocompatibility and have multifunctional functions, including the ability to direct ligands towards specific spots for preferential aggregation, hence enabling their utilization in specialized applications. This paper provides an overview of the characteristics, modifications, and synthesis methods of MXene nanomaterials. The present article also delivers a comprehensive assessment of the practical uses of MXene-based nanomaterials in biomedicine, with a particular focus on biosensing, bioimaging, antibacterial effects, implants, and multifunctional therapeutic platforms. This paper also presents a discussion of the future prospects and challenges associated with the applications of MXenes in the biomedicine field.
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    MXene-based materials for enhanced water quality: Advances in remediation strategies
    (Elsevier BV, 2025-02-01)
    Ali Mohammad Amani
    ;
    Milad Abbasi
    ;
    Atena Najdian
    ;
    Farzaneh Mohamadpour
    ;
    Seyed Reza Kasaee
    Two-dimensional MXenes are promising candidates for water treatment because of their large surface area (e.g., exceeding 1000 m²/g for certain structures), high electrical conductivity (e.g., >1000 S/m), hydrophilicity, and chemical stability. Their strong sorption selectivity and effective reduction capacity, exemplified by heavy metal adsorption efficiencies exceeding 95 % in several studies, coupled with facile surface modification, make them suitable for removing diverse contaminants. Applications include the removal of heavy metals (e.g., achieving >90 % removal of Pb(II)), dye removal (e.g., demonstrating >80 % removal of methylene blue), and radioactive waste elimination. Furthermore, 3D MXene architecture exhibit enhanced performance in antibacterial activities (e.g., against bacteria), desalination rejection percentage, and photocatalytic degradation of organic contaminants. However, several challenges have remained, which necessitate further investigation into toxicity (e.g., assessing effects on aquatic organisms), scalability, and cost-effectiveness of large-scale production. This review summarizes recent advancements in 3D MXene-based functional materials for wastewater treatment and water remediation, critically analyzing their both potential and limitations.
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    Multifunctional MXenes nanocomposite platforms for biosensing and wearable sensor technologies
    (Springer Science and Business Media LLC, 2025-02-01)
    Ali Mohammad Amani
    ;
    Hesam Kamyab
    ;
    Ehsan Vafa
    ;
    Alireza Jahanbin
    ;
    Milad Abbasi
    MXenes are nanostructures with unique characteristics, such as hydrophilicity, large surface area, strong metallic conductivity, strong ion transport capabilities, biocompatibility, minimal diffusion barrier, and easy functionalization, which make these compounds suitable for bioanalytical applications. These materials are formed of transition metallic nitrides, carbides, or carbonitrides. Owing to their unique properties, MXenes have gained interest in various fields, including sustainable energy generation, fuel cells, supercapacitors, electronics, and catalysis. The composition and layered structure have made MXenes particularly appealing to biosensing applications. They can be used in electrochemical biosensors because of their high conductivity and multilayered architecture, which ensure the retention of activity in immobilized biomolecules. This review highlights the application of MXenes in electrochemical and optical biosensors, identifying future requirements and potential in this sector, particularly in the development of wearable sensors and platforms with integrated biomolecule detection.
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    Synthesis of Fe3O4 MIL-101-OH/Chitosan for adsorption and release of doxorubicin
    (Elsevier BV, 2025-01-01)
    Iman Najafipour
    ;
    Nafiseh Emami
    ;
    Pegah Sadeh
    ;
    Adonis Amoli
    ;
    Sareh Mosleh-Shirazi
    This study reports the synthesis and characterization of a magnetic composite metal-organic framework, The Fe3O4@MIL-101-OH/Chitosan nanocomposite was used for the first time to adsorb and release the drug doxorubicin (DOX). The nanocomposite was characterized using scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR), Brunauer-Emmett-Teller (BET), X-ray diffraction (XRD), and vibrating sample magnetometry (VSM). The characterization results showed that the synthesized nanocomposite has a crystalline structure and good magnetic properties. Also, this nanocomposite has a high specific surface area (610.36 m2/g). In this article, the effect of pH, contact time, and drug concentration on DOX adsorption were investigated, and the results showed that at optimal conditions, pH = 8, contact time = 90 min, and drug concentration is 350 ppm, the adsorption capacity of MIL-101-OH/Chitosan and Fe3O4@MIL-101-OH/Chitosan are equal to 185 and 174.3 mg/g. The adsorption data follows pseudo-second-order kinetic and Langmuir isotherm models. The adsorption was physical and reversible. As a result, drug release was checked. The Fe3O4@MIL-101-OH/Chitosan exhibited a controlled release over the period of 84 h at pH 5 and reached 80 % of the DOX release rate after 60 h. In conclusion, the Fe3O4@MIL-101-OH/Chitosan composite has great potential as a drug delivery system as a result of its high adsorption capacity and magnetic properties. This research provides a promising approach for the development of novel drug delivery systems for cancer therapy.
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