Carbon Beam Therapy Overcomes the Radiation Resistance of Uterine Cervical Cancer Originating from Hypoxia

Nakano, Takashi; Suzuki, Yoshiyuki; Ohno, Tatsuya; Kato, Shingo; Suzuki, Miyuki; Morita, Shinroku; Sato, Shin-ichiro; Oka, Kuniyuki; Tsujii, Hirohiko

doi:10.1158/1078-0432.ccr-05-1907

Cited by 129 publications

(82 citation statements)

References 28 publications

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“…High LET radiation could overcome such radioresistance because of its diminished susceptibility to the OER effect. In a clinical trial of high LET carbon ion beam, Nakano et al compared its efficacy against hypoxic and normoxic cervical tumors and showed similar disease-free survival between hypoxic (<20 mmHg) and oxygenated (>20 mmHg) tumors suggesting that high LET radiation can overcome the radioresistance caused by tumor hypoxia [90]. Modeling analysis, however, suggest that the reduction of OER with high LET radiation under the clinical tumor hypoxic environment (0.5-20 mmHg) is relatively moderate with approximately 15% benefit over photon [85].…”

Section: Effect Of Cell Cycle and Oxygenationmentioning

confidence: 99%

“…The same model was also used to find that the RBE of two other alpha particle emitters, 148 Gd and 223 Ra, is 7.4 ± 2.4 and 5.4 ± 0.9, respectively [39]. In addition, in vivo studies of alpha emitter 213 Bi labeled peptide found an RBE of 2-3 for control of colon cancer and surprisingly close to 1.0 for marrow toxicity using beta emitter 90 Y labeled peptide as reference [40,41]. Nayak et al found similar RBE of 3.4 for 213 Bi labeled DOTATOC when treating pancreatic adenocarcinoma cells using 137 Cs as reference radiation [42].…”

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confidence: 98%

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Alpha Particle Emitter Radiolabeled Antibody for Metastatic Cancer: What Can We Learn from Heavy Ion Beam Radiobiology?

Song¹,

Senthamizhchelvan²,

Hobbs³

et al. 2012

Antibodies

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Alpha-particle emitter labeled monoclonal antibodies are being actively developed for treatment of metastatic cancer due to the high linear energy transfer (LET) and the resulting greater biological efficacy of alpha-emitters. Our knowledge of high LET particle radiobiology derives primarily from accelerated heavy ion beam studies. In heavy ion beam therapy of loco-regional tumors, the modulation of steep transition to very high LET peak as the particle approaches the end of its track (known as the Bragg peak) enables greater delivery of biologically potent radiation to the deep seated tumors while sparing normal tissues surrounding the tumor with the relatively low LET track segment part of the heavy ion beam. Moreover, fractionation of the heavy ion beam can further enhance the peak-to-plateau relative biological effectiveness (RBE) ratio. In contrast, internally delivered alpha particle radiopharmaceutical therapy lack the control of Bragg peak energy deposition and the dose rate is determined by the administered activity, alpha-emitter half-life and biological kinetics of the radiopharmaceutical. The therapeutic ratio of tumor to normal tissue is mainly achieved by tumor specific targeting of the carrier antibody. In this brief overview, we review the radiobiology of high LET radiations learned from ion beam studies and identify the features that are also applicable for the development of alpha-emitter labeled antibodies. The molecular mechanisms underlying DNA double strand break repair response to high LET radiation are also discussed.

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Section: Effect Of Cell Cycle and Oxygenationmentioning

confidence: 99%

mentioning

confidence: 98%

Alpha Particle Emitter Radiolabeled Antibody for Metastatic Cancer: What Can We Learn from Heavy Ion Beam Radiobiology?

Song¹,

Senthamizhchelvan²,

Hobbs³

et al. 2012

Antibodies

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show abstract

Section: Introductionmentioning

confidence: 99%

“…In comparison to photon based treatment techniques, protons have the potential to further reduce doses to OAR [19,28]. Small series of cervix cancer patients have been treated with carbon ions [12,22] and for a small number of patients protons were used as a boost modality [15].The aim of this study was to evaluate the potential benefit of proton beam therapy compared to standard conformal photon therapy as well as intensity modulated photon beam therapy (IMXT) for locally advanced cervix cancer. For proton beam therapy we considered two options.…”

mentioning

confidence: 99%

Assessment of Improved Organ at Risk Sparing for Advanced Cervix Carcinoma Utilizing Precision Radiotherapy Techniques

Georg

Georg²,

Hillbrand³

et al. 2008

Strahlenther Onkol

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“…It was reported that Bcl-2-overexpressing HeLa cells are more resistant to γ-rays (0.2 keV/µm) and helium ions (16.2 keV/µm) than neomycin resistance geneexpressing HeLa cells, whereas heavy ions (76.3-1610 keV/µm) yield similar survival regardless of Bcl-2 overexpression. This implies that heavy-ion radiotherapy may be equally effective against CSCs (64) and that carbon ion beam radiotherapy may not induce CSC repopulation in contrast to X-ray radiotherapy.…”

Section: Radiotherapy: the Potential Of Carbon Ion Beam Therapy In Rementioning

confidence: 99%

Cancer stem cells: The potential of carbon ion beam radiation and new radiosensitizers (Review)

et al. 2015

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Abstract. Cancer stem cells (CSCs) are a small population of cells in cancer with stem-like properties such as cell proliferation, multiple differentiation and tumor initiation capacities. CSCs are therapy-resistant and cause cancer metastasis and recurrence. One key issue in cancer therapy is how to target and eliminate CSCs, in order to cure cancer completely without relapse and metastasis. To target CSCs, many cell surface markers, DNAs and microRNAs are considered as CSC markers. To date, the majority of the reported markers are not very specific to CSCs and are also present in nonCSCs. However, the combination of several markers is quite valuable for identifying and targeting CSCs, although more specific identification methods are needed. While CSCs are considered as critical therapeutic targets, useful treatment methods remain to be established. Epigenetic gene regulators, microRNAs, are associated with tumor initiation and progression. MicroRNAs have been recently considered as promising therapeutic targets, which can alter the therapeutic resistance of CSCs through epigenetic modification. Moreover, carbon ion beam radiotherapy is a promising treatment for CSCs. Evidence indicates that the carbon ion beam is more effective against CSCs than the conventional X-ray beam. Combination therapies of radiosensitizing microRNAs and carbon ion beam radiotherapy may be a promising cancer strategy. This review focuses on the identification and treatment resistance of CSCs and the potential of microRNAs as new radiosensitizers and carbon ion beam radiotherapy as a promising therapeutic strategy against CSCs.

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Carbon Beam Therapy Overcomes the Radiation Resistance of Uterine Cervical Cancer Originating from Hypoxia

Cited by 129 publications

References 28 publications

Alpha Particle Emitter Radiolabeled Antibody for Metastatic Cancer: What Can We Learn from Heavy Ion Beam Radiobiology?

Alpha Particle Emitter Radiolabeled Antibody for Metastatic Cancer: What Can We Learn from Heavy Ion Beam Radiobiology?

Assessment of Improved Organ at Risk Sparing for Advanced Cervix Carcinoma Utilizing Precision Radiotherapy Techniques

Cancer stem cells: The potential of carbon ion beam radiation and new radiosensitizers (Review)

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