To Alfred Deakin

To access publisher full text version of this article. Please click on the hyperlink in Additional Links fieldIt has been proposed that hypoxia favors the growth of tumor cells over normal cells, particularly tumor cells carrying TP53 mutations. Cytogenetic studies of breast cancer have shown that highly complex karyotypes seen in direct harvest preparations are rarely detected after short-term culture. In this study, 34 paired samples of breast carcinomas and grossly nontumorous tissue from the same breast were cultured at 20 and 5% (12 samples) or 20 and 0% oxygen (22 samples). Both carcinoma samples and nontumorous tissue survived at 0% oxygen. Recovery for 24 hours at 20% produced good yields for cytogenetic analysis. Lower oxygen levels did not specifically stimulate growth of tumor cells. Samples with TP53 mutations showed a consistently increased growth under anaerobic hypoxic conditions. Culture at 5% oxygen did not generally reveal more karyotypic abnormalities than found at 20%. In the samples cultured at 0 and 20%, karyotypic abnormalities were detected only in anaerobic hypoxic culture in two cases. Of the only four samples where more complex karyotypes were detected in the low-oxygen culture, two were TP53 mutated. Hypoxic treatment followed by recovery at 20% oxygen may thus increase the yield of complex karyotypes from a subset of breast carcinomas, particularly those with mutated TP53

Nordic biological specimen banks as basis for studies of cancer causes and control--more than 2 million sample donors, 25 million person years and 100,000 prospective cancers

To access publisher full text version of this article. Please click on the hyperlink in Additional Links fieldThe Nordic countries have a long tradition of large-scale biobanking and comprehensive, population-based health data registries linkable on unique personal identifiers, enabling follow-up studies spanning many decades. Joint Nordic biobank-based studies provide unique opportunities for longitudinal molecular epidemiological research. The purpose of the present paper is to describe the possibilities for such joint studies, by describing some of the major Nordic biobank cohorts with a standardised calculation of the cancer incidence in these cohorts. Altogether two million donors have since 1966 donated more than four million biological samples, stored at -20 degrees C to -135 degrees C, to 17 biobank cohorts in Finland, Iceland, Norway and Sweden. As a result of joint database handling principles, the accuracy of personal identifiers and completeness of follow-up for vital status in all participating biobanks was improved. Thereafter, the cancer incidence was determined using follow-up through the national cancer registries. Biobanks based on random samples of population typically showed slightly lower cancer incidence rates than the general population, presumably due to better participation rates among health-conscious subjects. On the other hand, biobanks including samples for viral screening or clinical testing showed 1.5 to 2.1 fold increased incidence of cancer. This excess was very high immediately after sampling, but for some cancer sites remained elevated for years after clinical sampling. So far, more than 100 000 malignant neoplasms have occurred after sample donation, and the annual increase of the cancer cases in these cohorts is about 10 000. The estimates on the population-representativity of the biobanks will assist in interpretation of generalizability of results of future studies based on these samples, and the systematic tabulations of numbers of cancer cases will serve in study power estimations. The present paper summarizes optimal study designs of biobank-based studies of cancer