Peripheral blood stem cells (PBSCs) are increasingly used as the source of hematopoietic stem cells, but there are large variations in harvest outcome between individuals mobilized by granulocyte colony-stimulating factor (G-CSF). We examined the effects of donor characteristics and procedure factors on the day 1 CD34+ cell yield in 373 unrelated healthy donors. G-CSF was administered subcutaneously at a planned dose of 8.3 to 11 microg/kg daily for 5 days, followed by harvest started on day 5 of G-CSF treatment. Of the 373 donors, 159 (42.6%) had the radial artery as the inlet access for harvest. Poor day 1 cell yield was defined as <10x10(6) CD34+ cells/L of processed blood for the first apheresis; 62 donors (16.6%) did not attain this threshold. The male donors had significantly higher yields at harvest compared with the female donors. The female donors had higher CD34+ cell yields if the circulation access was through an artery than if is was through a vein. In a multiple regression analysis, donor age, sex, body mass index (BMI), preharvest white blood cell and circulating immature cell counts, access type, and flow rate correlated with day 1 yield. Female sex, older age, venous access, and a higher flow rate were significantly associated with greater risk for a day 1 poor yield of CD34+ cells (odds ratio=3.0074, 1.045, 4.3362, and 1.1131, respectively). A higher BMI may decrease the risk (odds ratio=0.8472). In donors at higher risk for poor CD34+ cell yield, strategies for increasing CD34+ cells must be considered.
We successfully obtained the normal CBC and WBC DC reference values of the cord blood in Taiwan. Gender and delivery routes were important confounding factors that influenced the cord blood CBC and WBC DC values.
Granulocyte colony-stimulating factor (G-CSF) is now widely used for stem cell mobilization. We evaluated the role of post-G-CSF white blood cell (WBC) counts and donor factors in predicting adverse events and yields associated with mobilization. WBC counts were determined at baseline, after the third and the fifth dose of G-CSF in 476 healthy donors. Donors with WBC ≥ 50 × 10(3)/μL post the third dose of G-CSF experienced more fatigue, myalgia/arthralgia, and chills, but final post-G-CSF CD34(+) cell counts were similar. Although the final CD34(+) cell count was higher in donors with WBC ≥ 50 × 10(3)/μL post the fifth G-CSF, the incidence of side effects was similar. Females more frequently experienced headache, nausea/anorexia, vomiting, fever, and lower final CD34(+) cell count than did males. Donors with body mass index (BMI) ≥ 25 showed higher incidences of sweat and insomnia as well as higher final CD34(+) cell counts. Donor receiving G-CSF ≥ 10 μg/kg tended to experience bone pain, headache and chills more frequently. Multivariate analysis indicated that female gender is an independent factor predictive of the occurrence of most side effects, except for ECOG > 1 and chills. Higher BMI was also an independent predictor for fatigue, myalgia/arthralgia, and sweat. Higher G-CSF dose was associated with bone pain, while the WBC count post the third G-CSF was associated with fatigue only. In addition, one donor in the study period did not complete the mobilization due to suspected anaphylactoid reaction. Observation for 1 h after the first injection of G-CSF is required to prevent complications from unpredictable side effects.
Allogeneic hematopoietic stem cell transplantation is now an important treatment for numerous diseases. Donation of hematopoietic stem cells, either through bone marrow (BM) harvesting or peripheral blood stem cell (PBSC) collection, is a well-established and generally accepted procedure. The BM is aspirated from the posterior iliac crest under spinal or general anesthesia, and common side effects include fatigue and local pain. PBSC collection requires 4-6 days of G-CSF injections and leukapheresis 1-2 times. Common side effects of these procedures include bone pain, fatigue, and headache. The side effects of BM and PBSC collections are mostly transient and well tolerated. Severe adverse events are uncommon in healthy donors. At present, there is no definitive evidence to show that the stem cell donation increases the risk of marrow failure or cancer development. Nevertheless, all donors must be carefully evaluated and fully informed before donation. Donors must be able to provide informed consent without being coerced or pressured. Donors and graft products must be examined for potential agents to avoid transmitting infections and other diseases that may jeopardize donor's health during stem cell collection or recipient's well being after transplantation. Understanding the potential physical and psychological complications of stem cell donation and factors that may increase risks is very important to ensure that transplantation physicians maintain positive attitude in conducting this benevolent practice.
The relationship between the features of bone marrow donor and the quality of marrow harvest has been unclear because most of bone marrow registries have multiple collection centers with somewhat different harvest procedures. We are able to address this issue for Tzu Chi General Hospital is the only collection center affiliated with Tzu Chi Taiwan Bone Marrow Registry. Between November 1997 and March 2002, data of 286 healthy unrelated donors was analyzed to correlate with the cell density of total nucleated cell in bone marrow harvests. The harvest procedure was standardized by single-hole harvest needle under general anesthesia. The operation staffs were restricted within the members of Oncology-Hematology division. The results showed that the cell density of bone marrow harvest was positively correlated with donor body weight and peripheral white blood cell count P = 0.0475, P < 0.0001, but negatively correlated with the total volume of bone marrow harvest P < 0.0001. We recommend that if multiple human leukocyte antigen-matched donors are available, donor with higher body weight and/or higher white blood cell count be selected for allogeneic bone marrow transplantation.
To improve bone marrow (BM) harvest of the volunteer donors in our institute, we changed from the single-hole needle to the multi-side-hole needle after March 2002, and examined the midway total nucleated cell (TNC) counts during collection after September 2004. The aims of this retrospective study were to evaluate BM harvest yields obtained through different strategies and to examine the correlation between final and midway BM harvests. The distribution of BM harvesting by different strategies was 235 donors with single-hole needles (group A), 389 donors with 5-side-hole needles (group B), and 365 donors with 5-side-hole needles and midway TNC counts (group C). The nucleated cell density of the collected BM was significantly improved by modifying the harvest strategy (0.202 × 10(8)/mL in group A, 0.219 × 10(8)/mL in group B, and 0.250 × 10(8)/mL in group C; P < .001). The percentage of unacceptable TNC dose (<2 × 10(8)/kg) was also decreased in all 3 groups (to 5.9%, 3.6%, and 0%, respectively; P < .001). Multiple regression analysis revealed that donor weight, white blood cell count, and harvest strategy were positively correlated with BM TNC density (P < .001), whereas harvested BM volume was negatively correlated with TNC density (P < .001). On linear regression analysis, highly significant correlations were noted between midway and final TNC densities (r = 0.8774; P < .001) as well as between harvested BM volume and TNC count (r = 0.7937; P < .001). Changing the harvesting needle and checking the midway TNC count improved the harvest outcome.
BACKGROUND: The outcome of peripheral blood stem cell (PBSC) harvest depends on mobilization and leukapheresis. Some poor harvests might not be directly related to poor mobilizations. STUDY DESIGN AND METHODS: We retrospectively analyzed the results of 793 consecutive healthy donors who underwent PBSC donation to evaluate the impact of low mean corpuscular volume (MCV) of red blood cells on the outcomes of hematopoietic stem cell mobilization and leukapheresis. RESULTS: The circulating CD34+ cells in peripheral blood after five doses of granulocyte–colony‐stimulating factor injection were similar in donors with low MCV and those with normal MCV (68.0 × 106/L vs. 69.2 × 106/L, p = 0.38). The procedural settings were not different between the two groups. However, the apheresis outcome of donors with low MCV was significantly lower in total CD34+ cells, cell dose, apheresis yield, and collection efficiency than those with normal MCV (277.6 × 106 vs. 455.0 × 106; 4.9 × 106/kg vs. 8.2 × 106/kg; 16.9 × 106/L vs. 27.3 × 106/L; 0.285 vs. 0.388; all p < 0.0001). Similar results were noticed in subgroup analysis using the severity of microcytosis and Mentzer index for the donors with MCV of less than 80 fL. The collection efficiency was significantly correlated with the MCV (r = 0.30, p < 0.0001). CONCLUSION: Low MCV was associated with poor apheresis outcomes in PBSC donors. This effect is not related to poor mobilization of CD34+ cells into the peripheral blood. Further studies to elucidate the detailed mechanism and develop strategy to avoid poor harvest are necessary.
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