Background Obstructive sleep apnea‐hypopnea syndrome (OSAHS) is a common breathing disorder during sleep with potential lethality and multi‐complications. Polysomnography (PSG) is now the golden standard for the diagnosis obstructive sleep apnea‐hypopnea syndrome. However, PSG is expensive and time‐consuming. Therefore, it is important to find inexpensive and convenient biomarkers for the diagnosis of OSAHS. Objective The present study aimed to explore the potential diagnostic value of HIF‐1α for OSAHS and its clinical significance. Methods This study consisted of 368 patients admitted to the sleep laboratory. The patients were classified according to their apnea‐hypopnea index (AHI) scores as OSA negative (AHI < 5), mild‐moderate (AHI:5‐30), and severe OSA (AHI > 30), and severe OSA treated with continuous positive airway pressure (CPAP). qRT‐PCR was used to detect mRNA levels in the plasma; Pearson's correlation analysis was performed to analyze the correlation of HIF‐1α mRNA level and the clinicopathological factors of OSAHS; ROC curve was constructed to evaluate the diagnostic value of HIF‐1α mRNA. Results HIF‐1α mRNA was significantly up‐regulated in the plasma of OSAHS patients, especially patients with severe OSAHS. HIF‐1α mRNA was positively correlated with the AHI and ODI but negatively correlated with the mean oxygen saturation in patients with OSAHS. Results of ROC curve showed that HIF‐1α is a sensitive biomarker for the diagnosis of OSAHS, especially severe OSAHS. Conclusions HIF‐1α mRNA might be used as s a convenient and inexpensive method for triaging OSAHS patients PSG assessment in the hospital and evaluate the curative effect.
This study investigated the dynamic characteristics of thermocouples by using double-pulse laser excitation for dynamic temperature calibration under extreme conditions. An experimental device was constructed for double-pulse laser calibration; the device uses a digital pulse delay trigger to precisely control the double-pulse laser to achieve sub-microsecond dual temperature excitation with adjustable time intervals. The time constants of thermocouples under single-pulse laser excitation and double-pulse laser excitation were evaluated. In addition, the variation trends of thermocouple time constants under different double-pulse laser time intervals were analyzed. The experimental results indicated that the time constant increases and then decreases with the decrease in the time interval of the double-pulse laser. A method for dynamic temperature calibration was established for the evaluation of the dynamic characteristics of temperature sensors.
By designing a field calibration device for temperature indicators, this paper proposed a method for field calibration of indicators based on an integrated thermostat with cold junction compensation to overcome the current problems with conventional methods, which include long duration before constant temperature at cold junction, non-portable design, low accuracy of temperature compensation. The thermostat integrated in the device can achieve rapid thermal control while remaining portable based on the miniaturized structure that the thermocouple terminals can placed in the thermostat and an algorithm for thermostat control. After error analysis and experimental verification, reliable results were obtained to prove that this method has the advantages of portability and efficiency compared with conventional methods.
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