TY - JOUR
T1 - Pharmacological strategies to spare normal tissues from radiation damage
T2 - Useless or overlooked therapeutics?
AU - Bourgier, Céline
AU - Levy, Antonin
AU - Vozenin, Marie Catherine
AU - Deutsch, Eric
PY - 2012/12/1
Y1 - 2012/12/1
N2 - Half of all the patients with a solid malignant tumor will receive radiation therapy (RT) with a curative or palliative intent during the course of their treatment. Deleterious effects may result in acute and chronic toxicities that reduce the long-term health-related quality of life of these patients. High-tech RT enables precise beam delivery that conforms closely to the shape of tumors yielding an improved efficacy/toxicity ratio. However, sophisticated RT will not completely prevent toxicity in the irradiated field, especially as normal tissue constraints are offset by dose escalation or concurrent chemotherapy. Pharmacological agents can be used before or after RT to reduce side effects and are classified based on the timing of RT delivery. Radioprotectors, used as a molecular prophylactic strategy before RT, are mostly based on antioxidant properties. Currently, amifostine is the only radioprotector approved for use in the clinic. Mitigators, given during or shortly after RT, reduce the action of cellular ionizing radiation on normal tissues before the emergence of symptoms. Lastly, a treatment is the administration of an agent once symptoms have developed in order to reverse those that are mostly due to fibrosis. This review presents the major known physiopathological mechanisms involved in radiation response and tissue damage for which potential pharmacological candidates are emerging. We discuss the potential clinical relevance of such therapeutics in the era of high-precision radiotherapy.
AB - Half of all the patients with a solid malignant tumor will receive radiation therapy (RT) with a curative or palliative intent during the course of their treatment. Deleterious effects may result in acute and chronic toxicities that reduce the long-term health-related quality of life of these patients. High-tech RT enables precise beam delivery that conforms closely to the shape of tumors yielding an improved efficacy/toxicity ratio. However, sophisticated RT will not completely prevent toxicity in the irradiated field, especially as normal tissue constraints are offset by dose escalation or concurrent chemotherapy. Pharmacological agents can be used before or after RT to reduce side effects and are classified based on the timing of RT delivery. Radioprotectors, used as a molecular prophylactic strategy before RT, are mostly based on antioxidant properties. Currently, amifostine is the only radioprotector approved for use in the clinic. Mitigators, given during or shortly after RT, reduce the action of cellular ionizing radiation on normal tissues before the emergence of symptoms. Lastly, a treatment is the administration of an agent once symptoms have developed in order to reverse those that are mostly due to fibrosis. This review presents the major known physiopathological mechanisms involved in radiation response and tissue damage for which potential pharmacological candidates are emerging. We discuss the potential clinical relevance of such therapeutics in the era of high-precision radiotherapy.
KW - Antioxidants
KW - Fibrosis
KW - Mitigation
KW - Radiation therapy
KW - Radioprotection
KW - Treatment
UR - http://www.scopus.com/inward/record.url?scp=84867986903&partnerID=8YFLogxK
U2 - 10.1007/s10555-012-9381-9
DO - 10.1007/s10555-012-9381-9
M3 - Review article
C2 - 22706781
AN - SCOPUS:84867986903
SN - 0167-7659
VL - 31
SP - 699
EP - 712
JO - Cancer and Metastasis Reviews
JF - Cancer and Metastasis Reviews
IS - 3-4
ER -