Xunbin Wei

In vivo imaging of specialized bone marrow endothelial microdomains for tumour engraftment.

The organization of cellular niches is known to have a key role in regulating normal stem cell differentiation and regeneration, but relatively little is known about the architecture of microenvironments that support malignant metastasis. Using dynamic in vivo confocal imaging, here we show that murine bone marrow contains unique anatomic regions defined by specialized endothelium. This vasculature expresses the adhesion molecule E-selectin and the chemoattractant stromal-cell-derived factor 1 (SDF-1) in discrete, discontinuous areas that influence the homing of a variety of tumour cell lines. Disruption of the interactions between SDF-1 and its receptor CXCR4 inhibits the homing of Nalm-6 cells (an acute lymphoblastic leukaemia cell line) to these vessels. Further studies revealed that circulating leukaemic cells can engraft around these vessels, suggesting that this molecularly distinct vasculature demarcates a microenvironment for early metastatic tumour spread in bone marrow. Finally, purified haematopoietic stem/progenitor cells and lymphocytes also localize to the same microdomains, indicating that this vasculature might also function in benign states to demarcate specific portals for the entry of cells into the marrow space. Specialized vascular structures therefore appear to delineate a microenvironment with unique physiology that can be exploited by circulating malignant cells.

Selective Cell Targeting with Light-Absorbing Microparticles and Nanoparticles

We describe a new method for selective cell targeting based on the use of light-absorbing microparticles and nanoparticles that are heated by short laser pulses to create highly localized cell damage. The method is closely related to chromophore-assisted laser inactivation and photodynamic therapy, but is driven solely by light absorption, without the need for photochemical intermediates (particularly singlet oxygen). The mechanism of light-particle interaction was investigated by nanosecond time-resolved microscopy and by thermal modeling. The extent of light-induced damage was investigated by cell lethality, by cell membrane permeability, and by protein inactivation. Strong particle size dependence was found for these interactions. A technique based on light to target endogenous particles is already being exploited to treat pigmented cells in dermatology and ophthalmology. With exogenous particles, phamacokinetics and biodistribution studies are needed before the method can be evaluated against photodynamic therapy for cancer treatment. However, particles are unique, unlike photosensitizers, in that they can remain stable and inert in cells for extended periods. Thus they may be particularly useful for prelabeling cells in engineered tissue before implantation. Subsequent irradiation with laser pulses will allow control of the implanted cells (inactivation or modulation) in a noninvasive manner.

In vivo flow cytometer for real-time detection and quantification of circulating cells

An in vivo flow cytometer is developed that allows the real-time detection and quantification of circulating fluorescently labeled cells in live animals. A signal from a cell population of interest is recorded as the cells pass through a slit of light focused across a blood vessel. Confocal detection of the excited fluorescence allows continuous monitoring of labeled cells in the upper layers of scattering tissue, such as the skin. The device is used to characterize the in vivo kinetics of red and white blood cells circulating in the vasculatúre of the mouse ear. Potential applications in biology and medicine are discussed.

In vivo flow cytometry: a new method for enumerating circulating cancer cells.

The fate of circulating tumor cells is an important determinant of their ability to form distant metastasis. Here, we demonstrate the use of in vivo flow cytometry as a powerful new method for detecting quantitatively circulating cancer cells. We specifically examine the circulation kinetics of two prostate cancer cell lines with different metastatic potential in mice and rats. We find that the cell line and the host environment affect the circulation kinetics of prostate cancer cells, with the intrinsic cell line properties determining the initial rate of cell depletion from the circulation and the host affecting cell circulation at later time points.

Imaging molecular expression on vascular endothelial cells by in vivo immunofluorescence microscopy.

Molecular expression on the vascular endothelium is critical in regulating the interaction of circulating cells with the blood vessel wall. Leukocytes as well as circulating cancer cells gain entry into tissue by interacting with adhesion molecules on the endothelial cells (EC). Molecular targets on the EC are increasingly being explored for tissue-specific delivery of therapeutic and imaging agents. Here we use in vivo immunofluorescence microscopy to visualize the endothelial molecular expression in the vasculature of live animals. High-resolution images are obtained by optical sectioning through the intact skin using in vivo confocal and multiphoton microscopy after in situ labeling of EC surface markers with fluorescent antibodies. Other vascular beds such as the bone marrow and ocular blood vessels can be imaged with little or no tissue manipulation. Live imaging is particularly useful for following the dynamic expression of inducible molecules such as E-selectin during an inflammatory response.

Real-time Detection of Circulating Apoptotic Cells by In Vivo Flow Cytometry

Survival of cancer cells in the circulation is an important step in metastasis. However, the fate of circulating tumor cells is difficult to assess with conventional methods that require blood sampling. We report the first in situ measurement of circulating apoptotic cells in live animals using in vivo flow cytometry, a novel method [1–3] that enables real-time detection and quantification of circulating cells without blood extraction. Injected cancer cells undergo cell death within 1–2 hr after entering the mouse circulation. Apoptotic cells are rapidly cleared from the circulation with a half-life of ~10 min. Real-time monitoring of circulating apoptotic cells can be useful for detecting early changes in disease processes, as well as for monitoring response to therapeutic intervention. To detect circulating apoptotic cells in vivo, annexin-V conjugated to Alexa Fluor 647 (AF647) was used to label exposed phosphatidylserine on the cell surface. The long wavelength of AF647 fluorescence (Molecular Probes, OR) allows its detection through blood with minimum attenuation by red blood cells. In initial studies conducted to demonstrate that our instrument had sufficient sensitivity to detect individual annexin-Vlabeled apoptotic cells in vivo, we used MatLyLu prostate cancer cells pretreated with camptothecin [4] as a positive control. We verified that >80% of the camptothecin-treated cells undergo apoptosis by conventional flow cytometry (i.e., >80% of the treated cells were FITC–annexin V positive and propidium iodide negative). The camptothecin-treated cells were then labeled with the AF647-conjugated annexin-V and injected into the mouse intravenously. The circulating annexin-V + cells were measured by focusing a He–Ne laser beam onto an ear vessel and detecting the fluorescent bursts as individual cells flowed

An optical platform for cell tracking in adult zebrafish.

Adult zebrafish are being increasingly used as a model in cancer and stem cell research. Here we describe an integrated optical system that combines a laser scanning confocal microscope (LSCM) and an in vivo flow cytometer (IVFC) for simultaneous visualization and cell quantification. The system is set up specifically for non‐invasive tracking of both stationary and circulating cells in adult zebrafish (casper) that have been engineered to be optically transparent. Confocal imaging in this instrument serves the dual purpose of visualizing fish tissue microstructure and an imaging‐based guide to locate a suitable vessel for quantitative analysis of circulating cells by IVFC. We demonstrate initial testing of this novel instrument by imaging the transparent adult zebrafish casper vasculature and tracking circulating cells in CD41‐GFP/Gata1‐DsRed transgenic fish whose thrombocytes/erythrocytes express the green and red fluorescent proteins. In vivo measurements allow cells to be tracked under physiological conditions in the same fish over time, without drawing blood samples or sacrificing animals. We also discuss the potential applications of this instrument in biomedical research.