Biological response of cancer cells to radiation treatment

Baskar, Rajamanickam; Dai, Jiawen; Nei, Wen Long; Yeo, Reuben J.; Yeoh, Kheng Wei

doi:10.3389/fmolb.2014.00024

Cited by 499 publications

(404 citation statements)

References 101 publications

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“…Although it is believed over a century that cancer cells were more radiosensitive compared to the normal cells, to completely eliminate the cancer cells, higher doses must be delivered to the tumor. This leads to more toxic effect on the surrounding normal tissues [66] that could affect a patient's quality of life. Consequently, this will bring radiation dose reductions or treatment delays that can lead to poor therapeutic outcome [67] .…”

Section: Radiotherapy and Therapeutic Ratiomentioning

confidence: 99%

Research and Development of Radioprotective Agents: A Mini-Review

Saaya

Katsube

Xie

et al. 2017

International Journal of Radiology

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The research and development (R&D) of radioprotective agents (RAs) have been conducting since seven decades ago, and the safety and protection against undesirable effects of ionizing radiation (IR) has become an important issue especially for the benefit of patients receiving the radiotherapy, in addition to the applications in nuclear industry, military, outer space exploration and accidental exposures. Although the technology advancement makes the radiotherapy a promising better treatment by maximizing the effect of IR to the cancer cells, there are still needs for improvement in minimizing the toxicity to the normal cells. Aiming at providing the new researchers in the radiation protection field with an overall view for R&D of the RAs, this mini-review elucidates in brief a general understanding of the IR and its effects on the cell, the concepts of radiotherapy and therapeutic ratio, the categories of RAs and their mechanisms, and discusses on the strategies and challenge for R&D of the RAs.

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Section: Radiotherapy and Therapeutic Ratiomentioning

confidence: 99%

Research and Development of Radioprotective Agents: A Mini-Review

Saaya

Katsube

Xie

et al. 2017

International Journal of Radiology

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“…Radiation affects cells directly by damaging DNA and indirectly by exciting water molecules and producing free radicals. Exposure to γ‐radiation mediates the lysis of water, generating reactive oxygen species (ROS) and causing functional deficiency and apoptosis of cells 2, 3, 4. In certain tumors, cancer cell survival rates after radiotherapy are high (e.g., early‐stage laryngeal cancer and nonsmall cell lung cancer) 5.…”

Section: Introductionmentioning

confidence: 99%

Radiation‐Sensitive Dendrimer‐Based Drug Delivery System

Chou

Yuh

et al. 2017

Advanced Science

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Combination of chemotherapy and radiotherapy is used to enhance local drug delivery while reducing off‐target tissue effects. Anticancer drug doxorubicin (DOX) is loaded into l‐cysteine modified G4.5 dendrimer (GC/DOX) and released at different pH values in the presence and absence of γ‐radiation. Presence of γ‐radiation significantly improves DOX release from the GC/DOX under acidic pH conditions, suggesting that GC dendrimer is a radiation‐sensitive drug delivery system. GC/DOX is further evaluated by determining cytotoxicity in uterine cervical carcinoma HeLa cells. GC/DOX shows high affinity for cancer cells and effective drug release following an external stimulus (radiation exposure), whereas an in vivo zebrafish study confirms that l‐cysteine acts as a radiosensitizer. GC/DOX treatment combined with radiotherapy synergistically and successfully inhibits cancer cell growth.

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“…[3] Radiotherapy is another important treatment currently used for several tumors, through which cancer cells are either directly killed upon DNA damage by depositing high physical energy of radiation, or indirectly due to the release of free radicals. [4] Nowadays the most novel anti-cancer strategies are the targeted-therapy and immunotherapy. The cancer targeted-therapy uses small molecules that can block fundamental pathways or mutant proteins essential for tumor growth.…”

Section: Introductionmentioning

confidence: 99%

Role of adenosine in tumor progression: focus on A2B receptor as potential therapeutic target

Sissi¹,

Morello²

2017

JCMT

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Adenosine receptors are a family of G-coupled receptors which mediate the antiinflammatory and immune-suppressive effects of adenosine in a damaged tissue. A large number of evidence indicate that the accumulation of adenosine under hypoxic conditions favors tumor progression, helping cancer cells to evade immune responses. Tumor cells and/ or lymphoid and myeloid cells can express the adenosine-generating enzyme CD73 and/or A 2A receptor, which in turn strongly suppresses an effective T-cell-mediated response, while promotes the activity of suppressive cells such as Treg and myeloid-derived suppressor cells. CD73 inhibitors and A 2A antagonists, either as single agents, or in combination with immune-checkpoints inhibitors such as anti PD-1 monoclonal antibodies, are currently in Phase I clinical trial in cancer patients. Recent studies show that A 2B receptor plays an important role in mediating the pro-tumor effects of adenosine, since its selective blockade can inhibit tumor growth in some murine tumor models. Targeting A 2B receptor reduces immunosuppression induced by myeloid cells and inhibits the stromal cells activity within the tumor microenvironment, limiting tumor angiogenesis and metastatic processes. Here, the authors review the current data on involvement of A 2B receptor in regulating tumor progression and discuss the development of A 2B receptor inhibitors as potential therapeutic agents in cancer treatment. Key words:CD73/A 2 adenosine receptors axis, A 2B adenosine receptor, tumor immunity, tumor metastasis, tumor angiogenesis, cancer treatment ABSTRACTArticle history:

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Biological response of cancer cells to radiation treatment

Cited by 499 publications

References 101 publications

Research and Development of Radioprotective Agents: A Mini-Review

Research and Development of Radioprotective Agents: A Mini-Review

Radiation‐Sensitive Dendrimer‐Based Drug Delivery System

Role of adenosine in tumor progression: focus on A2B receptor as potential therapeutic target

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