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Transition metal-based nanozymes: Classification, catalytic mechanisms and emerging biomedical applications

Abstract

Transition metal -based nanozymes, which exhibit intrinsic enzyme -like capacities, have several advantages over natural enzymes, including excellent stability, abundant metal sources, controllable activity, and inexpensive preparation processes. Nanozymes are characterized by interesting physicochemical properties, including photoluminescence, superparamagnetism, and special optical properties. Recently, various transition metal -based nanozyme platforms have been developed to target single or multiple substrates. The catalytic properties of nanozymes can be regulated by microenvironmental factors such as pH, oxygenation level, and concentration of H 2 O 2 , and also by a magnetic field, light, ultrasound, and heat. Thus, nanozyme signals can be maximized and tailored for disease diagnosis and treatment. Prompted by these inherent advantages, new approaches for diagnosis, treatment, and theranostics are emerging and gaining momentum. In this review, we summarize the preparation, catalytic mechanisms, and properties of transition metal -based nanozymes and highlight their emerging biomedical applications, including disease diagnosis, cancer therapy, imaging, and antibacterial infections. We anticipate that this review will be significant for improving our understanding of the capacities of metal -based nanozymes and motivating broader applications in several biomedical fields.

article Review

date_range 2024

language English

link Link of the paper

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Zhang Dandan

Chen Qing

Ren Qunxiang

Zhong Wenbin

Zhang Hongjin

Wang Guannan

Zhang Yang

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Nanozyme

Transition metal

Catalytic property regulation

Biomedical application

Therapy

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Assessment of reinforced concrete building damages following the Kahramanmaraş earthquakes in Malatya, Turkey (February 6, 2023)

Abstract

Earthquakes of magnitude Mw = 7.7 and Mw = 7.6 hit the city of Kahramanmaraş (Turkey) on 6 February 2023. These earthquakes caused serious damage in 11 provinces in Turkey resulting in over 50,000 deaths and huge economic losses with the collapse of thousands of buildings. Two consecutive devastating earthquakes have severely damaged the reinforced concrete building stock located in Malatya. There are many reasons reinforced concrete structures suffer damage under the influence of seismic loads. These reasons can be listed as material and section properties that do not comply with earthquake codes, workmanship defects, ground parameters that are not considered and design errors, as seen in field investigations after earthquakes in Turkey in the past. In this research, a field study was conducted on reinforced concrete buildings damaged after the earthquakes in Malatya province. The causes of structural damages in reinforced concrete buildings between 6–26 years of age were assessed in terms of design and material defects. The structural damages were mainly caused due to insufficient stirrups in structural members, short column, strong beam–weak column, failures of infill walls, soft story type collapse, poor concrete quality, and reinforcement corrosion. In addition to the field investigation, the spectrum relationships created using raw acceleration data obtained from DEMP (Disaster and Emergency Management Presidency) stations in Malatya province were compared with the design response spectra.

article Article

date_range 2024

language English

link Link of the paper

Collapsed buildings

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