A simplified method of CD34+ cell determination for peripheral blood progenitor cell transplantation and correlation with clinical engraftment.

Enumeration of CD34+ cells by flow cytometry is the recognized standard for quantitating progenitor cells for peripheral blood progenitor cell (PBPC) transplantation. Although many clinical studies have confirmed that the time to neutrophil and platelet engraftment is inversely proportional to the number of CD34+ cells infused, the minimum number of CD34+ cells necessary to acheive rapid engraftment has not been satisfactorily determined. The lack of a standardized method for quantitation of CD34+ cells by flow cytometry (FCM) is often cited as the reason for this ambiguity. This report describes an FCM method for CD34+ cell determination that is simple, highly reproducible, comparatively inexpensive, and validated by excellent correlation with clinical engraftment. Pheresis samples are stained and fixed within 4 hours of collection. Two hundred fifty thousand events are acquired as list mode data using a forward scatter threshold. The discrete CD34+ population is enumerated using a CD34-phycoerythrin FL2 vs. side scatter plot and Paint-A-Gate Pro software. The method was validated by excellent statistical correlation with clinical engraftment. Using this method, we determined the number of CD34+ progenitor cells necessary to achieve rapid engraftment to be 2 x 10(6)/kg.

Purging of small cell lung cancer cells from human bone marrow using ethiofos (WR-2721) and light-activated merocyanine 540 phototreatment.

One limitation of autologous bone marrow transplantation for patients with cancer has been the presence of tumor cells in the bone marrow. Methods to eliminate tumor cells while preserving hematopoietic stem cells have been sought. The present study was performed to analyze the in vitro effectiveness of light-activated merocyanine 540 phototreatment (LAMP) and an aminothiol (ethiofos) as a marrow-purging regimen for small cell lung cancer (SCLC). Two human SCLC cell lines (ATCC HTB-119 and HTB-120) were treated with LAMP and exposed to light for varying periods of time up to 120 min. LAMP reduced SCLC cell proliferation and colony formation in a light exposure-dependent manner; colony formation was not totally inhibited until light exposure of 120 min was used. At this light exposure interval, multipotential hematopoietic progenitors, colony-forming units-granulocyte, erythroid, macrophage, megakaryocyte (CFU-GEMM), were substantially reduced. In an attempt to diminish hematopoietic toxicity, SCLC cells were incubated with ethiofos (formerly WR-2721) for 1 hour before LAMP. SCLC colony formation was eliminated at light exposure intervals (90 min or less) which had no inhibitory effect on CFU-GEMM. Ethiofos did not protect CFU-GEMM from LAMP inhibition at 120 min. Ethiofos alone had no effect on the SCLC or hematopoietic cells. When normal bone marrow was contaminated with 1 or 5% SCLC cells, ethiofos plus 60 min of LAMP eliminated SCLC cells but had no effect on CFU-GEMM. The results suggest that ethiofos sensitized SCLC cells to LAMP; thus ethiofos-enhanced LAMP may be an effective method for removing metastatic SCLC cells from bone marrow used for autologous marrow transplantation after high dose chemotherapy.