Ultrasound‐Activated Piezoelectric Nanoparticles Trigger Microglia Activity Against Glioblastoma Cells

Montorsi, Margherita; Pucci, Carlotta; De Pasquale, Daniele; Marino, Attilio; Ceccarelli, Maria Cristina; Mazzuferi, Martina; Bartolucci, Martina; Petretto, Andrea; Prato, Mirko; Debellis, Doriana; De Simoni, Giorgio; Pugliese, Giammarino; Labardi, Massimiliano; Ciofani, Gianni

doi:10.1002/adhm.202304331

Cited by 4 publications

(2 citation statements)

References 120 publications

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“…Various piezoresponse values were recorded on different fibers, as summarized in Figure 7. This illustrates the ability of CE-FM-PFM to characterize the local piezoresponse of compliant polymeric nanostructures, like the present ultrafine fibers, or even polymeric nanoparticles [33], loosely adhered to the substrate, conveniently and reliably. The measurements were conducted over two months on fibers transferred on different substrates (e.g., silicon and gold) and with different AFM probes.…”

Section: Characterization Of Pan Fiber Meshesmentioning

confidence: 66%

“…As evident from the reported data, a wide range of values was obtained for the Various piezoresponse values were recorded on different fibers, as summarized in Figure 7. This illustrates the ability of CE-FM-PFM to characterize the local piezoresponse of compliant polymeric nanostructures, like the present ultrafine fibers, or even polymeric nanoparticles [33], loosely adhered to the substrate, conveniently and reliably. measurement mechanism of PFM, where the detected piezo displacement depends on the direction of the polar axis of the fiber when transferred onto the conductive substrate.…”

Section: Characterization Of Pan Fiber Meshesmentioning

confidence: 66%

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Piezoelectric Yield of Single Electrospun Poly(acrylonitrile) Ultrafine Fibers Studied by Piezoresponse Force Microscopy and Numerical Simulations

Montorsi,

Zavagna,

Scarpelli

et al. 2024

Polymers

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Quantitative converse piezoelectric coefficient (d33) mapping of polymer ultrafine fibers of poly(acrylonitrile) (PAN), as well as of poly(vinylidene fluoride) (PVDF) as a reference material, obtained by rotating electrospinning, was carried out by piezoresponse force microscopy in the constant-excitation frequency-modulation mode (CE-FM-PFM). PFM mapping of single fibers reveals their piezoelectric activity and provides information on its distribution along the fiber length. Uniform behavior is typically observed on a length scale of a few micrometers. In some cases, variations with sinusoidal dependence along the fiber are reported, compatibly with a possible twisting around the fiber axis. The observed features of the piezoelectric yield have motivated numerical simulations of the surface displacement in a piezoelectric ultrafine fiber concerned by the electric field generated by biasing of the PFM probe. Uniform alignment of the piezoelectric axis along the fiber would comply with the uniform but strongly variable values observed, and sinusoidal variations were occasionally found on the fibers laying on the conductive substrate. Furthermore, in the latter case, numerical simulations show that the piezoelectric tensor’s shear terms should be carefully considered in estimations since they may provide a remarkably different contribution to the overall deformation profile.

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Section: Characterization Of Pan Fiber Meshesmentioning

confidence: 66%

Section: Characterization Of Pan Fiber Meshesmentioning

confidence: 66%

Piezoelectric Yield of Single Electrospun Poly(acrylonitrile) Ultrafine Fibers Studied by Piezoresponse Force Microscopy and Numerical Simulations

Montorsi,

Zavagna,

Scarpelli

et al. 2024

Polymers

View full text Add to dashboard Cite

show abstract

3D Printing and Biomedical Applications of Piezoelectric Composites: A Critical Review

Li,

Shan,

Chen

et al. 2024

Adv Materials Technologies

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Piezoelectric composites have received widespread attentions in the fields of biomedicine and in vitro wearable devices due to their ability to convert mechanical forces into charge signals. The preparation of piezoelectric composites with complex structures through 3D printing technology can not only effectively improve their piezoelectric output, but also enable their customized therapeutic applications. This paper first introduces the types of piezoelectric composites and reviews the 3D printing technology commonly used in their preparation, analyzing the advantages and disadvantages of each 3D printing technology. Then, the state‐of‐the‐art of the biomedical applications of piezoelectric composites, including drug sustained‐release, wound healing promotion, bone tissue cells growth promoting, neurorehabilitation stimulating, ultrasonic diagnosis, and in vivo biosensing and in vitro wearable sensing, are emphasized. Finally, the main factors affecting the applications of 3D printed piezoelectric composites are outlooked, and an in‐depth discussion on the challenges toward 3D printed piezoelectric composites are analyzed. This review is believed to provide some fundamental knowledge of 3D printed piezoelectric composites.

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Nanocatalytic medicine enabled next-generation therapeutics for bacterial infections

Ge,

Jiang,

Lin

2024

Materials Today Bio

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Ultrasound‐Activated Piezoelectric Nanoparticles Trigger Microglia Activity Against Glioblastoma Cells

Cited by 4 publications

References 120 publications

Piezoelectric Yield of Single Electrospun Poly(acrylonitrile) Ultrafine Fibers Studied by Piezoresponse Force Microscopy and Numerical Simulations

Piezoelectric Yield of Single Electrospun Poly(acrylonitrile) Ultrafine Fibers Studied by Piezoresponse Force Microscopy and Numerical Simulations

3D Printing and Biomedical Applications of Piezoelectric Composites: A Critical Review

Nanocatalytic medicine enabled next-generation therapeutics for bacterial infections

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