Accurate grading of 3 synchronous liposarcomas assessed by PET-CT in a single patient.

Positron emission tomography (PET) with 2-fluoro-deoxyglucose (FDG) has become an established imaging modality that can accurately and noninvasively differentiate malignant neoplasms from benign masses. It is increasingly being used to grade malignant neoplasms as well and has almost replaced other studies like gallium 67-citrate scans for metabolic imaging. We describe an interesting case of 3 synchronous liposarcomas with different radio-opacifications on computed tomography (CT).

Evidence for alternative candidate genes near RB1 involved in clonal expansion of in situ urothelial neoplasia.

In this paper, we present whole-organ histologic and genetic mapping studies using hypervariable DNA markers on chromosome 13 and then integrate the recombination- and single-nucleotide polymorphic sites (SNPs)-based deletion maps with the annotated genome sequence. Using bladders resected from patients with invasive urothelial carcinoma, we studied allelic patterns of 40 microsatellite markers mapping to all regions of chromosome 13 and 79 SNPs located within the 13q14 region containing the RB1 gene. A whole-organ histologic and genetic mapping strategy was used to identify the evolution of allelic losses on chromosome 13 during the progression of bladder neoplasia.

Amplification/overexpression of a mitotic kinase gene in human bladder cancer.

Background: The mitotic kinase-encoding gene STK15/BTAK/ AuroraA is associated with aneuploidy and transformation when overexpressed in mammalian cells. STK15 overexpression activates an unknown oncogenic pathway that involves centrosome amplification and results in missegregation of chromosomes. Because clinical prognosis and tumor aneuploidy are tightly linked in human bladder cancer, we examined whether increased STK15 copy number and protein levels are linked to aneuploidy in bladder cancers.

The seed and soil hypothesis: vascularisation and brain metastases.

The development of a relevant mouse model for the establishment and growth of brain metastases is essential for study of the biology and therapy of brain metastasis. Injection of human tumour cells into the internal carotid artery of syngeneic or nude mice produces experimental metastases in specific regions of the brain; these are not due to patterns of initial cell arrest, motility, or invasiveness, but rather to the ability of metastatic tumour cells to grow. Whether the progressive growth of brain metastases depends on neovascularisation is not clear.