Zhengqin Gu

Circulation times of prostate cancer and hepatocellular carcinoma cells by in vivo flow cytometry

In metastasis, the cancer cells that travel through the body are capable of establishing new tumors in locations remote from the site of the original disease. To metastasize, a cancer cell must break away from its tumor and invade either the circulatory or lymphatic system, which will carry it to a new location, and establish itself in the new site. Once in the blood stream, the cancer cells now have access to every portion of the body. Here, we have used the “in vivo flow cytometer” to study if there is any relationship between metastatic potential and depletion kinetics of circulating tumor cells. The in vivo flow cytometer has the capability to detect and quantify continuously the number and flow characteristics of fluorescently labelled cells in vivo. We have improved the counting algorithm and measured the depletion kinetics of cancer cells with different metastatic potential. Interestingly, more invasive PC‐3 prostate cancer cells are depleted faster from the circulation than LNCaP cells. In addition, we have measured the depletion kinetics of two related human hepatocellular carcinoma (liver cancer) cell lines, high‐metastatic HCCLM3 cells, and low‐metastatic HepG2 cells. More than 60% HCCLM3 cells are depleted within the first hour. Interestingly, the low‐metastatic HepG2 cells possess noticeably slower depletion kinetics. In comparison, <40% HepG2 cells are depleted within the first hour. The differences in depletion kinetics might provide insights into early metastasis processes.

Circulation times of hepatocellular carcinoma cells by in vivo flow cytometry

Hepatocellular carcinoma (HCC) may metastasize to many organs. The survival rate is almost zero for metastatic HCC patients. Molecular mechanisms of HCC metastasis need to be understood better and new therapies must be developed. We have developed the

STUDYING THE ROLE OF MACROPHAGES IN CIRCULATING PROSTATE CANCER CELLS BY IN VIVO FLOW CYTOMETRY

Metastasis is a very complicated multi-step process and accounts for the low survival rate of the cancerous patients. To metastasize, the malignant cells must detach from the primary tumor and migrate to secondary sites in the body through either blood or lymph circulation. Macrophages appear to be directly involved in tumor progression and metastasis. However, the role of macrophages in affecting cancer metastasis has not been fully elucidated. Here, we have utilized an emerging technique, namely in vivo flow cytometry (IVFC) to study the depletion kinetics of circulating prostate cancer cells in mice and determine how depletion of macrophages by the liposome-encapsulated clodronate affects the depletion kinetics. Our results show different depletion kinetics of PC-3 cells between the macrophage-deficient group and the control group. The number of circulating tumor cells (CTCs) in the macrophage-deficient group decreases in a slower manner compared to the control mice group. The differences in depletion kinetics indicate that the absence of macrophages facilitates the stay of prostate cancer cells in circulation. In addition, our imaging data suggest that macrophages might be able to arrest, phagocytose and digest PC-3 cells. Therefore, phagocytosis may mainly contribute to the depletion kinetic differences. The developed methods elaborated here would be useful to study the relationship between macrophages and tumor metastasis in small animal cancer models.

Role of macrophages in circulating prostate cancer cells studied by in vivo flow cytometry

Macrophages appear to be directly involved in cancer progression and metastasis. However, the role of macrophages in influencing tumor metastasis has not been fully understood. Here, we have used an emerging technique, namely in vivo flow cytometry (IVFC) to study the depletion kinetics of circulating prostate cancer cells in mice and how depletion of macrophages by the liposome-encapsulated clodronate affects the depletion kinetics. Our results show different depletion kinetics of PC-3 prostate cancer cells between macrophage-deficient group and the control group. The number of circulating tumor cells (CTCs) in macrophage-deficient group decreases in a slower manner compared to the control mice group. The differences in depletion kinetics indicate that the absence of macrophages might facilitate the stay of prostate tumor cells in circulation. We speculate that macrophages might be able to arrest, phagocytose and digest PC-3 cancer cells. Therefore, the phagocytosis may mainly contribute to the differences in depletion kinetics. The developed methods here would be useful to study the relationship between macrophages and cancer metastasis in small animal tumor model.

Studying the role of macrophages in circulating prostate cancer cellsby in vivo flow cytometry

Metastasis is a very complicated multi-step process and accounts for the low survival rate of the cancerous patients. To metastasize, the malignant cells must detach from the primary tumor and migrate to secondary sites in the body through either blood or lymph circulation. Macrophages appear to be directly involved in tumor progression and metastasis. However, the role of macrophages in affecting cancer metastasis has not been fully elucidated. Here, we have utilized an emerging technique, namely in vivo flow cytometry (IVFC) to study the depletion kinetics of circulating prostate cancer cells in mice and how depletion of macrophages by the liposome-encapsulated clodronate affects the depletion kinetics. Our results show different depletion kinetics of PC-3 cells between macrophage-deficient group and the control group. The number of circulating tumor cells (CTCs) in macrophage-deficient group decreases in a slower manner compared to the control mice group. The differences in depletion kinetics indicate that the absence of macrophages facilitates the stay of prostate cancer cells in circulation. We speculate that macrophages might be able to arrest, phagocytose and digest PC-3 cells. Therefore, the phagocytosis may mainly contribute to the depletion kinetic differences. The developed methods here would be useful to study the relationship between macrophages and tumor metastasis in small animal cancer model.

Studying cancer metastasis potential by in-vivo flow cytometry and imaging

An in vivo flow cytometer and optical imaging are used to assess tumor cell spreading. The depletion rate of circulating tumor cells provides insights in early cancer metastasis. It is useful to understand the molecular mechanisms of tumor metastasis.