Pharmacological preconditioning for short-term ex vivo expansion of human umbilical cord blood hematopoietic stem cells by filgrastim.

Although umbilical cord blood (UCB) hematopoietic stem cell transplantation (UCBT) has emerged as a promising haematological reconstitution therapy for leukemias and other related disorders, the insufficient UCB stem cell dosage still hinders better clinical outcomes. Previous research efforts, by focusing on ex vivo UCB expansion capabilities have sought to benefit from well-known mechanisms of self-renewal characteristics of UCB stem cells. However, the long-term (> 21 days) in vitro culture period and the low neutrophil recovery significantly reduce the transplantability of such ex vivo expanded UCB stem cells. To overcome the latter hurdles in this study, a post-thaw, short-term ex vivo expansion methodology of UCB mononuclear (UCB-MN) and CD34(+) cells has been established. Notably, such effort was achieved through pharmacological preconditioned of UCB cultures by filgrastim agent already used in the clinical setting. In crucial cell populations implicated in the promotion of functional engraftment, the progression of free survival rates (PFS), a marked increase of 6.65 to 9.34 fold for UCB-MN and 35 to 49 fold for CD34(+) cells has been noticed. Overall, these results indicate that transplantation of pharmacologically-preconditioned ex vivo expansion of UCB stem and progenitor cells keep high promise upon transplantation to enhance therapeutic potential in everyday clinical practice.

Association of TNFα, TNFR1, and TNFR2 polymorphisms with sperm concentration and motility.

Tumor necrosis factor α (TNFα) is a multifunctional cytokine that regulates various cellular processes related to spermatogenesis. Two types of cell receptors, TNFR1 and TNFR2, mediate TNFα activity. In the present study, we sought to explore the association of TNFα -857C→T, TNFR1 36A→G, and TNFR2 676T→G polymorphisms with sperm concentration and motility. Two hundred ninety men were examined during infertility investigation; of those, 170 men were normozoospermic and 120 were oligospermic. Polymerase chain reaction analysis revealed significant differences in genotype distribution of the TNFR1 36A→G polymorphism between normozoospermic and oligospermic men. Men with oligozoospermia presented TNFR1 36A/A genotypes less frequently than normozoospermic men (P < .001). The presence of the TNFR1 36G allele was significantly increased in oligospermic men (P < .001). Furthermore, the presence of the TNFR1 36G allele was associated with lower sperm concentration in normozoospermic men (P < .03) and in the total study population (P < .001), and with lower sperm motility in normozoospermic men (P < .007) and in the total study population (P < .001). No significant associations were found between TNFα -857C→T and TNFR2 676T→G polymorphisms and semen quality. The TNFR1 36A allele is associated with increased sperm concentration and motility in our series, supporting the significance of TNFR1 gene in semen quality.