Zhuo Pan scite author profile

Cancer stem cell (CSC) is thought to be the major cause of radio-resistance and relapse post radiotherapy (RT). Recently ultra-high dose rate “FLASH-RT” evokes great interest for its decreasing normal tissue damages while maintaining tumor responses compared with conventional dose rate RT. However, the killing effect and mechanism of FLASH irradiation (FLASH-IR) on CSC and normal cancer cell are still unclear. Presently the radiation induced death profile of CSC and normal cancer cell were studied. Cells were irradiated with FLASH-IR (∼109 Gy/s) at the dose of 6–9 Gy via laser-accelerated nanosecond particles. Then the ratio of apoptosis, pyroptosis and necrosis were determined. The results showed that FLASH-IR can induce apoptosis, pyroptosis and necrosis in both CSC and normal cancer cell with different ratios. And CSC was more resistant to radiation than normal cancer cell under FLASH-IR. Further experiments tracing lysosome and autophagy showed that CSCs had higher levels of lysosome and autophagy. Taken together, our results suggested that the radio-resistance of CSC may associate with the increase of lysosome-mediated autophagy, and the decrease of apoptosis, necrosis and pyroptosis. To our limited knowledge, this is the first report shedding light on the killing effects and death pathways of CSC and normal cancer cell under FLASH-IR. By clarifying the death pathways of CSC and normal cancer cell under FLASH-IR, it may help us improve the understanding of the radio-resistance of CSC and thus help to optimize the future clinical FLASH treatment plan.

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Brilliant femtosecond-laser-driven hard X-ray flashes from carbon nanotube plasma

Shou

Wang

Lee

et al. 2022

Nat. Photon.

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Current research trends on microplastics pollution and impacts on agro-ecosystems: A short review

Dai

Shi

Zhang

et al. 2021

Separation Science and Technology

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Alpha-Particle Generation from H-¹¹B Fusion Initiated by Laser-Accelerated Boron Ions

Kong

Shou

et al. 2022

Laser Part. Beams

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Here, we report the generation of MeV alpha-particles from H-11B fusion initiated by laser-accelerated boron ions. Boron ions with maximum energy of 6 MeV and fluence of 109/MeV/sr@5 MeV were generated from 60 nm-thick self-supporting boron nanofoils irradiated by 1 J femtosecond pulses at an intensity of 1019 W/cm2. By bombarding secondary hydrogenous targets with the boron ions, 3 × 105/sr alpha-particles from H-11B fusion were registered, which is consistent with the theoretical yield calculated from the measured boron energy spectra. Our results demonstrated an alternative way toward ultrashort MeV alpha-particle sources employing compact femtosecond lasers. The ion acceleration and product measurement scheme are referential for the studies on the ion stopping power and cross section of the H-11B reaction in solid or plasma.

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Zhuo Pan

Super-Heavy Ions Acceleration Driven by Ultrashort Laser Pulses at Ultrahigh Intensity

Association of Cancer Stem Cell Radio-Resistance Under Ultra-High Dose Rate FLASH Irradiation With Lysosome-Mediated Autophagy

Brilliant femtosecond-laser-driven hard X-ray flashes from carbon nanotube plasma

Current research trends on microplastics pollution and impacts on agro-ecosystems: A short review

Alpha-Particle Generation from H-¹¹B Fusion Initiated by Laser-Accelerated Boron Ions

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Zhuo Pan

Super-Heavy Ions Acceleration Driven by Ultrashort Laser Pulses at Ultrahigh Intensity

Association of Cancer Stem Cell Radio-Resistance Under Ultra-High Dose Rate FLASH Irradiation With Lysosome-Mediated Autophagy

Brilliant femtosecond-laser-driven hard X-ray flashes from carbon nanotube plasma

Current research trends on microplastics pollution and impacts on agro-ecosystems: A short review

Alpha-Particle Generation from H-11B Fusion Initiated by Laser-Accelerated Boron Ions

Contact Info

Product

Resources

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Alpha-Particle Generation from H-¹¹B Fusion Initiated by Laser-Accelerated Boron Ions