Dr. Zelanna Goldberg
UCDMC-Cancer Center
4501 'X ' St.; Ste. G-126
Dept. of Radiation Oncology
Sacramento, CA 95817
Phone: 916-734-7749
Fax: 916-454-4614
E-mail: slmorey@ucdavis.edu
Number of Human Subjects projects reported: 1
| UCDCC-01-83294 | "Effects of Low Dose Ionizing Radiation on Gene Expression in Human Subjects Undergoing Radiotherapy" |
"Effects of Low Dose Ionizing Radiation on Gene Expression in Human Subjects Undergoing Radiotherapy"
Principal Investigator: Dr. Zelanna Goldberg, University of California - Davis Cancer Center
Project started in: 2001
Funding for Human Subjects Research:
This project does not involve the use of multiple protocols/subprojects.
Institutional Review Board (IRB) Review:
Type of Review: Full Board
Approving Institution: University of California - Davis Cancer Center
Most recent approval: 07/25/03
IRB approval number: 200311085-2
Number of human subjects who participated in this project/protocol/subproject in the last reporting period: 12
Reporting period for number of human subjects:
Fiscal Year 2003
Type(s) of Human Subjects Involvement:
Several investigations have demonstrated that significant biological effects can occur in animals, animal cells, immortalized human cell lines, and primary human cells after exposure to doses of ionizing radiation (IR) in the <1-10 cGy region. Examples of such effects include the induction of adaptive responses in which low dose exposures render cells less radiosensitive in response to a subsequent bout of exposure to higher dose IR, increases in cell proliferation, and increases in the ability of cells to repair some forms of DNA damage. Other evidence suggests low doses of IR, especially high Linear Energy Transfer (LET) alpha particles, can induce more overtly untoward effects, e.g., mutations, cell transformation and genomic instability. Little information, however, is available as to how these and other observations made with cultured cells mimic or even pertain to the actual in vivo condition, especially in humans. Yet, such knowledge is ultimately required for reducing the uncertainty of assessing human risks due to low dose IR (LDIR) exposures, as may be encountered in a variety of environmental scenarios. Toward filling this information void, the project uses biopsied tissues from informed and consenting volunteers who are to receive radiation therapy for treatment of their prostate cancers. Modern dosimetry utilizing computerized tomography based 3-dimensional radiation treatment planning and PEREGRINE Monte Carlo treatment planning provides accurate calculations of radiation dose delivered to target tissue and peripheral tissue outside of the high dose region. The target volume receives therapeutic dose, e.g., 2 Gy, whereas tissue sites and volumes that receive far lesser doses, i.e., 1-10 cGy can be defined, biopsied, and subjected to further study ex vivo along with tissue samples from the primary target sites.
Risks to the patients are related only to the 3 mm core skin biopsies and thus are minimal. All patients give informed consent for the biopsy procedure, and confidentiality is maintained as no information is reported in any way to identify the individual patient. This in vivo exposure system can also provide information on adaptive or other responses after repeated exposures since patients receiving radiation with curative intent are radiated daily, five days a week, for six to eight weeks. A further advantage of using patient biopsies is that of gaining insight into the cellular and molecular responses to very low dose IR in normal tissue, i.e., three dimensionally configured in an otherwise undisturbed microenvironment with intact vasculature. Further, freshly explanted tissue samples can be subjected to additional manipulation, like re-irradiations with higher dose IR.