Development of a Sampling Collection Device with Diagnostic Procedures.

Cervicovaginal fluid plays an important role in the detection of many female genital diseases, but the lack of suitable collection devices in the market severely challenges test success rate. Appropriate clinical sampling devices for cervicovaginal fluid collection would help physicians detect diseases and disease states more rapidly, efficiently, and accurately. The objective of this study was to develop a readily usable sampling collection device that would eliminate macromolecular interference and accurately provide specimens for further studies. This study was designed to develop an effective device to collect cervicovaginal fluid from women with symptoms of endometrial lesions, women appearing in the clinic for a routine Papanicolaou smear, and/or women seeking a routine gynecologic checkup. Paper-based assay, ELISA, and qNano were used to provide accurate diagnoses. A total of 103 patients successfully used the developed device to collect cervicovaginal fluid. Some of the collected specimens were used to detect glycogen, lactate, and pH for determining pathogen infection. Other specimen samples were tested for the presence of female genital cancer by comparing interleukin 6 concentration and microvesicle concentration. We proposed a noninvasive screening test for the diagnosis of female genital diseases using a dual-material collection device. The outer, nonwoven fabric portion of this device was designed to filter macromolecules, and the inner cotton portion was designed to absorb cervicovaginal fluid.

p15(PAF) is an Rb/E2F-regulated S-phase protein essential for DNA synthesis and cell cycle progression.

The p15(PAF)/KIAA0101 protein is a proliferating cell nuclear antigen (PCNA)-associated protein overexpressed in multiple types of cancer. Attenuation of p15(PAF) expression leads to modifications in the DNA repair process, rendering cells more sensitive to ultraviolet-induced cell death. In this study, we identified that p15(PAF) expression peaks during the S phase of the cell cycle. We observed that p15(PAF) knockdown markedly inhibited cell proliferation, S-phase progression, and DNA synthesis. Depletion of p15(PAF) resulted in p21 upregulation, especially chromatin-bound p21. We further identified that the p15(PAF) promoter contains 3 E2F-binding motifs. Loss of Rb-mediated transcriptional repression resulted in upregulated p15(PAF) expression. Binding of E2F4 and E2F6 to the p15(PAF) promoter caused transcriptional repression. Overall, these results indicate that p15(PAF) is tightly regulated by the Rb/E2F complex. Loss of Rb/E2F-mediated repression during the G1/S transition phase leads to p15(PAF) upregulation, which facilitates DNA synthesis and S-phase progression.