A co-culture, cryogenic SIMS methodology is presented for the quantitative analysis of cell type-dependent accumulation of boron delivered by BPA-F and BSH, two clinically approved drugs used in boron neutron capture therapy of cancer. T98G human glioblastoma cells were co-cultured with morphologically different normal LLC-PK1 epithelial cells or GM3348 human skin fibroblasts. Our freeze-fracture method of cryogenic sample preparation successfully fractured the different cell types grown together in co-cultures. Quantitative observations revealed an active uptake of boron from BPA-F in both T98G and LLC-PK1 cells but did not show cell type-dependent differences. Accumulation of BSH in all three cell types examined also did not reveal any cell type-dependent differences in co-cultures. As this method relies on the analysis, within the same field of SIMS imaging, of two different cell types that have been maintained under identical conditions of growth, drug exposure, sample preparation, and instrumental analysis, it provides the most effective approach for comparing cell type-specific differences in boron concentrations. The most effective applications of this method will be realized in testing the selectivity of experimental boronated compounds designed to specifically target tumor cells.
SummaryBoron measurements at subcellular scale are essential in boron neutron capture therapy (BNCT) of cancer as the nuclear localization of boron-10 atoms can enhance the effectiveness of killing individual tumour cells. Since tumours contain a heterogeneous population of cells in interphase as well as in the M phase (mitotic division) of the cell cycle, it is important to evaluate the subcellular distribution of boron in both phases.In this work, the secondary ion mass spectrometry (SIMS) based imaging technique of ion microscopy was used to quantitatively image boron from two BNCT agents, clinically used p-boronophenylalanine (BPA) and 3-[4-(ocarboran-1-yl)butyl]thymidine (N4), in mitotic metaphase and interphase human glioblastoma T98G cells. N4 belongs to a class of experimental BNCT agents, designated 3-carboranyl thymidine analogues (3CTAs), which presumably accumulate selectively in cancer cells due to a process referred to as kinase-mediated trapping (KMT). The cells were exposed to BPA for 1 h and N4 for 2 h. A CAMECA IMS-3f SIMS ion microscope instrument capable of producing isotopic images with 500 nm spatial resolution was used in the study. Observations were made in cryogenically prepared fast frozen, and freeze-fractured, freeze-dried cells. Three discernible subcellular regions were studied: the nucleus, Correspondence to: Subhash Chandra, Ph.D., Tel: 607-255-3884; fax: 607-254-4780; e-mail: sc40@cornell.edu a characteristic mitochondria-rich perinuclear cytoplasmic region, and the remaining cytoplasm in interphase T98G cells. In metaphase cells, the chromosomes and the cytoplasm were studied for boron localization. Intracellular concentrations of potassium and sodium also were measured in each cell in which the subcellular boron concentrations were imaged. Since the healthy cells maintain a K/Na ratio of approximately 10 due to the presence of Na-K-ATPase in the plasma membrane of mammalian cells, these measurements provided validation for cryogenic sample preparation and indicated the analysis healthy, well preserved cells. The BPA-treated interphase cells revealed significantly lower concentrations of boron in the perinuclear mitochondria-rich cytoplasmic region as compared to the remaining cytoplasm and the nucleus, which were not significantly different from each other. In contrast, the BPA-treated metaphase cells revealed significantly lower concentration of boron in their chromosomes than cytoplasm. In addition, the cytoplasm of metaphase cells contained significantly less boron than the cytoplasm of interphase cells. These observations provide valuable information on the reduced uptake of boron from BPA in mitotic cells for BPA-mediated BNCT. SIMS observations on N4 revealed that boron was distributed throughout the interphase and mitotic cells, including the chromosomes. The presence of boron in chromosomes of metaphase cells treated with N4 is indicative of a possible incorporation of this thymidine analogue into DNA. The 3-D SIMS imaging approach for the analysis of mitotic cells show...
Ion microscopy was used for subcellular quantitative imaging of the isotopes 10B and 11B in the same cell to evaluate boron delivery using a mixture of two neutron capture therapy drugs, p-boronophenylalanine-fructose (BPA-F) and sodium borocaptate (BSH). The application of 10B-labeled BPA-F and 11B-labeled BSH allowed independent imaging of both 10B and 11B in the same cell using a CAMECA IMS-3f ion microscope. Mixed-drug treatments were compared to single-drug exposures given under identical conditions. 10BPA-F delivered 10B heterogeneously to T98G human glioblastoma cells, with a significantly reduced concentration in an organelle-rich perinuclear region. The intracellular distribution of 11B from 11BSH contrasted with that of the 10B from 10BPA-F, with 11B distributed nearly homogeneously throughout cells. The subcellular distributions of 10B and 11B were sustained in mixed-drug treatments and resembled their localizations after the single-drug treatments. In both single- and mixed-drug treatments, cellular levels of 10B from 10BPA-F nearly doubled between 1 h and 6 h, with a 3:1 intracellular to nutrient medium partitioning, while cellular levels of 11BSH remained essentially unchanged. The net effect of the combined treatment with 10BPA-F and 11BSH was an additive delivery of boron to cells. This study introduces a novel approach for checking potential synergistic, antagonistic or simple additive delivery of two mixed boronated compounds in cellular/subcellular compartments.
Nuclear chemistry is a topic of great societal importance with applications in the realms of medicine, energy, and national security. Despite its significance, this area receives little attention in both K–12 and undergraduate education. This poor coverage arises in part from the lack of suitable educational resources to illustrate key concepts of nuclear chemistry. Here, we describe the development of two activities for the K–12 classroom, which are designed to assist instructors in communicating several conceptual aspects of nuclear chemistry. The first of these activities is an interactive game, called Isotope Rummy, which has been developed as a Lending Library kit through the Cornell Center for Materials Research (CCMR). This game informs students on the composition of the nucleus and factors that determine nuclear stability with respect to radioactive decay. The second activity, called Radiative versus Radioactive Decay, is designed for instructor-led outreach workshops or demonstrations. This activity gives examples of spontaneous radioactive and stimulated photoluminescent decay. We have performed the activities separately and together in various high school classrooms and as a full workshop at a student conference. Feedback obtained from both teachers and students indicates that these activities are helpful for fostering an understanding of several key concepts in nuclear chemistry.
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