Cerenkov Radiation Induced Photodynamic Therapy Using Chlorin e6-Loaded Hollow Mesoporous Silica Nanoparticles

Kamkaew, Anyanee; Cheng, Liang; Goel, Shreya; Valdovinos, Hector F.; Barnhart, Todd E.; Liu, Zhuang; Cai, Weibo

doi:10.1021/acsami.6b10255

Cited by 144 publications

(119 citation statements)

References 36 publications

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“…(e) Co‐localization in vivo therapy results. (Reprinted with permission from Shaffer et al (), Kamkaew et al () and Kotagiri et al (). Copyright 2017, 2016 and 2018 American Chemical Society and Nature Publishing Group)…”

Section: Cherenkov Radiation‐induced Pdtmentioning

confidence: 99%

“…Later, Thorek, Ogirala, Beattie, and Grimm (2013) studied Cherenkov radiation interacting with quantum dots for secondary Cherenkov-induced fluorescence imaging. Since that time several studies have reported that Cherenkov radiation can be exploited to activate PDT (Hartl, Hirschberg, Marcu, & Cherry, 2016;Kamkaew et al, 2016;Kotagiri, Sudlow, Akers, & Achilefu, 2015). Using Cherenkov radiation to induce PDT offers several potential advantages.…”

Section: Cherenkov Radiationmentioning

confidence: 99%

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Nanoparticles to mediate X‐ray‐induced photodynamic therapy and Cherenkov radiation photodynamic therapy

Cline

Delahunty

Xie

2018

WIREs Nanomed Nanobiotechnol

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Photodynamic therapy (PDT) has emerged as an attractive option for cancer treatment. However, conventional PDT is activated by light that has poor tissue penetration depths, limiting its applicability in the clinic. Recently the idea of using X-ray sources to activate PDT and overcome the shallow penetration issue has garnered significant interest. This can be achieved by external beam irradiation and using a nanoparticle scintillator as transducer. Alternatively, research on exploiting Cherenkov radiation from radioisotopes to activate PDT has also begun to flourish. In either approach, the most auspicious success is achieved using nanoparticles as either a scintillator or a photosensitizer to mediate energy transfer and radical production. Both X-ray induced PDT (X-PDT) and Cherenkov radiation PDT (CR-PDT) contain a significant radiation therapy (RT) component and are essentially PDT and RT combination. Unlike the conventional combination, however, in X-PDT and CR-PDT, one energy source simultaneously activates both processes, making the combination always in synchronism and the synergy potential maximized. While still in early stage of development, X-PDT and CR-PDT address important issues in the clinic and hold great potential in translation. This article is categorized under: Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease.

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Section: Cherenkov Radiation‐induced Pdtmentioning

confidence: 99%

Section: Cherenkov Radiationmentioning

confidence: 99%

Nanoparticles to mediate X‐ray‐induced photodynamic therapy and Cherenkov radiation photodynamic therapy

Cline

Delahunty

Xie

2018

WIREs Nanomed Nanobiotechnol

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“…The nanoparticles, termed nanophotosensitizers, were targeted to tumours via transferrin attached to the surface, and the PDT from the combination of titanium dioxide and [ 18 F]-FDG showed a significant survival benefit compared with either of the agents alone. This work utilized the internal CL to photoactivate the nanoconstruct for oxidation-based therapy, for the first time liberating photodynamic therapy from the need of an external excitation source, similar to the internal excitation of fluorochromes 57 , with similar work using 89 Zr-nanoconstruct combinations also demonstrating therapeutic efficacy 58 . This approach is attractive due to the potential utilization of photodynamic therapeutics with clinical radiotracers already in routine use.…”

Section: Cerenkov-activatable Probes and Therapiesmentioning

confidence: 99%

Utilizing the power of Cerenkov light with nanotechnology

2017

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The characteristic blue glow of Cerenkov luminescence (CL) arises from the interaction between a charged particle travelling faster than the phase velocity of light and a dielectric medium, such as water or tissue. As CL emanates from a variety of sources, such as cosmic events, particle accelerators, nuclear reactors and clinical radionuclides, it has been used in applications such as particle detection, dosimetry, and medical imaging and therapy. The combination of CL and nanoparticles for biomedicine has improved diagnosis and therapy, especially in oncological research. Although radioactive decay itself cannot be easily modulated, the associated CL can be through the use of nanoparticles, thus offering new applications in biomedical research. Advances in nanoparticles, metamaterials and photonic crystals have also yielded new behaviours of CL. Here, we review the physics behind Cerenkov luminescence and associated applications in biomedicine. We also show that by combining advances in nanotechnology and materials science with CL, new avenues for basic and applied sciences have opened.

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“…Recently, CR was also used as a light source for chemical and therapeutic applications (14)(15)(16). In 2015, Kotagiri et al (15) demonstrated the use of CR generated by the 18 F-FDG radionuclide to activate TiO 2 nanoparticles in vivo to produce reactive oxygen species (ROS) and suppress the growth of cancer cells.…”

mentioning

confidence: 99%

“…It has a band gap of 3.2 eV and absorbs UV light efficiently-properties that match the high-intensity regimen of CR. Kamkaew et al (16) reported a system with a 89 Zr radionuclide (Cerenkov radiation source) and chlorin e6 (photocatalyst) and demonstrated its advantage in ROS generation through CR. Two radionuclides-68 Ga and 18 F-were recently studied for their cellular uptake and effectiveness in cancer treatment (23,24).…”

mentioning

confidence: 99%

Design of Cerenkov Radiation–Assisted Photoactivation of TiO₂ Nanoparticles and Reactive Oxygen Species Generation for Cancer Treatment

Kavadiya

Biswas

2018

J Nucl Med

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The use of Cerenkov radiation to activate nanoparticles in situ was recently shown to control cancerous tumor growth. Although the methodology has been demonstrated to work, to better understand the mechanistic steps, we developed a mathematic model that integrates Cerenkov physics, light interaction with matter, and photocatalytic reaction engineering. Methods: The model describes a detailed pathway for localized reactive oxygen species (ROS) generation from the Cerenkov radiation-assisted photocatalytic activity of TiO 2 . The model predictions were verified by comparison to experimental reports in the literature. The model was then used to investigate the effects of various parameters-the size of TiO 2 nanoparticles, the concentration of TiO 2 nanoparticles, and the activity of the radionuclide 18 F-FDG-on the number of photons and ROS generation. Results: The importance of nanoparticle size in ROS generation for cancerous tumor growth control was elucidated, and an optimal size was proposed. Conclusion: The model described here can be used for other radionuclides and nanoparticles and can provide guidance on the concentration and size of TiO 2 nanoparticles and the radionuclide activity needed for efficient cancer therapy.

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Cerenkov Radiation Induced Photodynamic Therapy Using Chlorin e6-Loaded Hollow Mesoporous Silica Nanoparticles

Cited by 144 publications

References 36 publications

Nanoparticles to mediate X‐ray‐induced photodynamic therapy and Cherenkov radiation photodynamic therapy

Nanoparticles to mediate X‐ray‐induced photodynamic therapy and Cherenkov radiation photodynamic therapy

Utilizing the power of Cerenkov light with nanotechnology

Design of Cerenkov Radiation–Assisted Photoactivation of TiO₂ Nanoparticles and Reactive Oxygen Species Generation for Cancer Treatment

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Cerenkov Radiation Induced Photodynamic Therapy Using Chlorin e6-Loaded Hollow Mesoporous Silica Nanoparticles

Cited by 144 publications

References 36 publications

Nanoparticles to mediate X‐ray‐induced photodynamic therapy and Cherenkov radiation photodynamic therapy

Nanoparticles to mediate X‐ray‐induced photodynamic therapy and Cherenkov radiation photodynamic therapy

Utilizing the power of Cerenkov light with nanotechnology

Design of Cerenkov Radiation–Assisted Photoactivation of TiO2 Nanoparticles and Reactive Oxygen Species Generation for Cancer Treatment

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Design of Cerenkov Radiation–Assisted Photoactivation of TiO₂ Nanoparticles and Reactive Oxygen Species Generation for Cancer Treatment