Photon activated therapy (PAT) using monochromatic Synchrotron x-rays and iron oxide nanoparticles in a mouse tumor model: feasibility study of PAT for the treatment of superficial malignancy

Choi, Gi-Hwan; Seo, Sang Woo; Kim, Ki Hong; Kim, Hong-Tae; Park, Sung-Hwan; Lim, Jae‐Hong; Kim, Jongki

doi:10.1186/1748-717x-7-184

Cited by 37 publications

(22 citation statements)

References 24 publications

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“…Nanoradiator effect can be obtained from either Coulomb collision with ion beam or photoelectric absorption of X-ray photon. However, ion-beam irradiation may provide much better way in the energy delivery as well as Z-value independent interaction with nanoparticles compared with X-ray photon under the normal tissue tolerance [5,15].…”

Section: Discussionmentioning

confidence: 99%

Enhancement of Tumor Regression by Coulomb Nanoradiator Effect in Proton Treatment of Iron-Oxide Nanoparticle-Loaded Orthotopic Rat Glioma Model: Implication of Novel Particle Induced Radiation Therapy

Seo¹,

Jeon²,

Jeong³

et al. 2013

JCT

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Background: Proton-impact metallic nanoparticles, inducing low-energy electrons emission and characteristic X-rays termed as Coulomb nanoradiator effect (CNR), are known to produce therapeutic enhancement in proton treatment on experimental tumors. The purpose of this pilot study was to investigate the effect of CNR-based dose enhancement on tumor growth inhibition in an iron-oxide nanoparticle (FeONP)-loaded orthotopic rat glioma model. Methods: Proton-induced CNR was exploited to treat glioma-bearing SD rat loaded with FeONP by either fully-absorbed single pristine Bragg peak (APBP) or spread-out Bragg peak (SOBP) 45-MeV proton beam. A selected number of rats were examined by MRI before and after treatment to obtain the size and position information for adjusting irradiation field. Tumor regression assay was performed by histological analysis of residual tumor in the sacrificed rats 7 days after treatment. The results of CNR-treated groups were compared with the proton alone control. Results: Intravenous injection of FeONP (300 mg/kg) elevated the tumor concentration of iron up to 37 μg of Fe/g tissue, with a tumor-to-normal ratio of 5, 24 hours after injection. The group receiving FeONP and proton beam showed 65% -79% smaller tumor volume dose-dependently compared with the proton alone group. The rats receiving FeONP and controlled irradiation field by MR imaging demonstrated more than 95% -99% tumor regression compared with MRI-determined initial tumor size. Conclusions: Proton-impact FeONP produced therapeutic enhancement compared with proton alone in an orthotopic rat glioma model at a selected temporal point after treatment. Single BP proton beam could induce CNRbased dose enhancement and produce enhanced tumor regression that was comparable to SOBP treatment despite inhomogeneous tumor dose in the APBP-treated tumor. These results may suggest emergence of novel Particle Induced Radiation Therapy (PIRT) on malignant glioma.

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Section: Discussionmentioning

confidence: 99%

Enhancement of Tumor Regression by Coulomb Nanoradiator Effect in Proton Treatment of Iron-Oxide Nanoparticle-Loaded Orthotopic Rat Glioma Model: Implication of Novel Particle Induced Radiation Therapy

Seo¹,

Jeon²,

Jeong³

et al. 2013

JCT

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“…The RBE assessment is the most valuable study within the radiobiological trials and the most essential tool to reproduce the practical needs aimed at the radiotherapy schemes' development. The RBE using 10 % survival criteria for B-16 cells is 1.5, while a similar study, using the same object but with other incubation properties, was much lower -1.05 [2]. Even a higher RBE of 2.0 has been observed on the 2 Gy exposure level of mice melanoma cells (which is the fraction standard in the conventional radiotherapy schemes).…”

Section: Resultsmentioning

confidence: 71%

“…This issue can be resolved using a binary therapy method, in particular, the photon capture therapy (PCT). The metals selectively accumulated within the tumor are coupled with the Xrays' additional interaction, which finally results in the emission of the short range secondary ionization particles leading to the tumor dose enhancement [1,2]. The wide spread of the PCT method into the clinical practice is limited mostly by the lack of effective drugs and substances satisfying the method requirements: higher concentration in the tumor and precise dose escalation that could lead to the tumor growth suppression effect.…”

Section: Introductionmentioning

confidence: 99%

THE PHOTON CAPTURE THERAPY MODEL FOR IN VIVO AND IN VITRO STUDIES USING Au NANOCOMPOSITES WITH THE HYALURONIC ACID BASED COMPOUNDS

Koryakin¹,

Isaeva²,

Beketov³

et al. 2017

RadJ

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Abstract. This study provides the quantitative assessment of the photon-capture therapy efficiency using the X-ray facility and Au nanocomposite in solutions based on hyaluronic acid and melanin. The RBE using 10 % survival criteria for murine B-16 melanoma cell cultures was 1.5. The rats with implanted sarcoma M-1 were locally irradiated with 28-32 Gy of tumor dose. Irradiation in 28 Gy of cell cultures with the 4 mg of Au-based solution administered 15 minutes before irradiation, showed the similar efficiency as conventional 32 Gy. The skin reaction yield is dependent only on the absorbed dose. The therapeutic gain using the tumor growth suppression factor was 1.35, which is comparable to the RBE of B-16 cell cultures.

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“…The physical principle of photon activation therapy (PAT) consists of increasing the local release of energy (photoelectrons and Auger-electrons) that result from the photoeffect arising when the soft X-ray radiation interacts with atoms of elements with large atomic number Z [5][6][7], herewith prospects for use of gold nanoparticles in the PAT are shown in several publications [8,9]. This type of radiation therapy is most suitable for wide use in oncology practice since X-ray sources are mobile, relatively cheap and do not require special rooms with a powerful biological protection when operating and that creates conditions for PAT widespread use in the treatment of cancer patients.…”

Section: Introductionmentioning

confidence: 99%

The study of hyaluronic acid compounds for neutron capture and photon activation therapies

et al. 2014

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Abstract:The therapy of radioresistant tumors remains an urgent problem in medicine. To solve this problem neutron capture therapy (NCT) and photon activation therapy (PAT) are used. The essential feature of this such technique is the uptake of tumor chemical elements, which interact with thermal neutrons (NCT) and X-rays (PAT). The aims of the investigation were to study a biodistribution of the complexes of hyaluronic acid with boron (3 mg B mL -1 ) and gold (20 mg Au mL -1 ) in mice with melanoma B-16 after intratumoral administration. An optimal time for NCT was 30 minutes after administration when boron concentration in the tumor was more than 30 µg g -1 and exceeded boron content in surrounding tissues. The maximal gold content in tumor (180-260 mg g -1 ) was obtained in 30 minutes after the preparation introduction. The highest ratios of gold in tumor and surrounding tissues (a necessary condition for forming of the local absorbed dose in tumor) was obtained in 0.5 and 1 h. On the basis of the data obtained, it is possible to assume the perspectives of the non-toxic boron compounds for use in NCT and the gold compounds for use primarily as contrast agents for diagnostic purposes.

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Photon activated therapy (PAT) using monochromatic Synchrotron x-rays and iron oxide nanoparticles in a mouse tumor model: feasibility study of PAT for the treatment of superficial malignancy

Cited by 37 publications

References 24 publications

Enhancement of Tumor Regression by Coulomb Nanoradiator Effect in Proton Treatment of Iron-Oxide Nanoparticle-Loaded Orthotopic Rat Glioma Model: Implication of Novel Particle Induced Radiation Therapy

Enhancement of Tumor Regression by Coulomb Nanoradiator Effect in Proton Treatment of Iron-Oxide Nanoparticle-Loaded Orthotopic Rat Glioma Model: Implication of Novel Particle Induced Radiation Therapy

THE PHOTON CAPTURE THERAPY MODEL FOR IN VIVO AND IN VITRO STUDIES USING Au NANOCOMPOSITES WITH THE HYALURONIC ACID BASED COMPOUNDS

The study of hyaluronic acid compounds for neutron capture and photon activation therapies

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