RESUMO
PURPOSE: Our aim is to explore the relation between non-neoplastic bladder diseases and bladder cancer (BC) from a genetic level utilizing Mendelian randomization (MR). METHODS: Single nucleotide polymorphisms (SNPs) related to cystitis, bladder stones, and neuropathic bladder were gathered from the IEU genome-wide association studies database. Quality control on SNPs was performed via stringent screening criteria. The relation between non-neoplastic bladder diseases and BC risk was evaluated using inverse-variance weighted, MR-Egger, weighted median, simple mode, and weighted mode methods. Cochran's Q test was conducted to assess the heterogeneity of SNPs; in addition, the MR-Egger intercept test was employed to examine the horizontal pleiotropy of SNPs. Exposure and outcomes were validated using a validation database. Finally, BC was used as the exposure and non-neoplastic bladder diseases as the outcome to evaluate reverse causality. RESULTS: The outcomes showcased that genetically predicted cystitis is significantly correlated to a raised risk of BC (inverse-variance weighted: odds ratio [95%] = 1.1737 [1.0317, 1.3352], P = .0149), consistent with the BC validation cohort in the MR analysis. Nevertheless, no causal relation was found between bladder stone and neuropathic bladder with BC risk (P > .05). In this study, sensitivity analysis indicated no heterogeneity or horizontal pleiotropy. CONCLUSION: The study presents proof of a genetic-level causal relation between cystitis and increased BC risk, while bladder stones and neuropathic bladder do not show similar associations.
RESUMO
The nuclear resonant scattering (NRS) experiment requires photon-counting detectors with high time resolution, short dead time, large dynamic range, low noise, and large detection area. An 8-channel avalanche photodiode (APD) array detector system with high integrity, flexibility, and reliability has been developed to adapt to the demands of NRS experiments. The detector system mainly consists of four key parts: (i) an array-APD sensor, (ii) 8-channel integrated fast preamplifiers, (iii) the time-to-digital converter readout electronics, and (iv) a data acquisition system and EPICS support software. Remarkably, the system exhibits a time resolution of better than 500 ps and has a sufficiently low noise level, allowing for the lowest detection energy threshold of 4 keV. The performance of the new array-APD system as well as its real application in nuclear forward scattering (NFS) and nuclear resonant inelastic x-ray scattering (NRIXS) experiments was tested in two synchrotron facilities. With the new system, the NFS signal very close to the prompt electronic scattering signal can be extracted. Thanks to the customized EPICS-areaDetector-based control software, NRIXS spectra can be readily measured with time and energy information of the NRIXS signal stored in the raw data, which is promising for developing NRIXS data analysis in the time domain. The array-APD detector can be deployed for nuclear resonant scattering experiments at various synchrotron radiation facilities.