HPLC法同时测定清心莲子饮中黄芩苷及甘草酸铵两种成分的含量

建立高效液相色谱方法,以清心莲子饮中黄芩苷以及甘草酸铵两种成分为研究对象,对其进行含量测定;采用Elite C18色谱柱,以不同的溶剂作为流动相,结果两种成分的R2均大于0.9990,测定的含量分别为34.9566和4.6613mg·剂^(-1);实验仪器及测定方法结果良好,适用于清心莲子饮中黄芩苷以及甘草酸铵的含量测定,为该制剂的质量控制提供了依据。

HPLC法测定清心莲子饮中京尼平苷酸的含量

目的建立采用HPLC法测定清心莲子饮中京尼平苷酸含量的方法;方法采用Elite HPLC C18(4.6×25mm,5μm)色谱柱,甲醇-0.5%HAc为流动相进行梯度洗脱,检测波长为254nm,流速为1.0mL·min-1;结果在0.18~0.90μg范围内京尼平苷酸线性关系良好,回归方程为:Y=11.185X+0.065,平均加样回收率为101.05%;结论该含量测定方法简便,准确,重现性好,适用于清心莲子饮中京尼平苷酸的含量测定。

高效液相色谱法测定半夏泻心汤物质基准中盐酸小檗碱的含量

目的采用高效液相色谱连用紫外检测器检测经典名方半夏泻心汤中盐酸小檗碱的含量。方法色谱柱以十八烷基硅烷键合硅胶为填充剂,以乙腈0.05mol·L^(-1)及KH_(2)PO_(4)溶液(50∶50)为流动相,流速设置为1mL·min^(-1),检测波长为345nm。结果盐酸小檗碱出峰时间为9.5min左右,阴性样品对盐酸小檗碱的检测影响较小,试验方法有效。盐酸小檗碱在0.26~1.04μg之间呈良好线性关系,得回归方程为:Y=61.583X-0.9668,R^(2)=0.999。最终确定半夏泻心汤物质基准的盐酸小檗碱每剂含量范围33.12~61.50mg。结论该方法有效简便的测定出半夏泻心汤物质基准中盐酸小檗碱的含量,为经典名方半夏泻心汤的进一步研究与发展奠定了基础。

基于网络药理学与分子对接技术探究逍遥丸治疗乳腺增生的作用机制

用网络药理学方法进行逍遥丸治疗乳腺增生过程的机制研究。通过中药系统药理学数据库和分析平台(TCMSP)进行逍遥丸活性成分的搜集和筛选,将纳入的化合物成分通过TCMSP数据库进行成分的靶点预测;在GeneCards数据库,NCBI基因数据库以及OMIM数据库进行乳腺增生疾病靶点筛选;取药物靶点和疾病靶点作韦恩图,并利用共有靶点在String数据库中作PPI网络图,利用拓扑分析和MCODE聚类分析筛选核心靶点和核心基因;在cytoscape 3.8.0软件中进行关键活性成分的筛选;关键靶点使用String数据库进行GO分析和KEGG分析,将相关结果导入Cytoscape3.8.0绘制成分—疾病—通路—靶点网络图。结果表明,筛选得到逍遥丸各药活性成分及靶点,其中与乳腺增生相关的有169个靶点。STAT3、AKT1、MAPK1、JUN、MAPK3等20个靶点为该药治疗乳腺增生的关键靶点,HTR2A、IL2、TOP2A、PCNA、MMP1为该药治疗乳腺增生的核心基因。槲皮素(quercetin)、山奈酚(kaempferol)、叶黄素(luteolin)、柚皮素(naringenin)、甘草酮a(licochalcone a)、7-甲氧基-2-甲基异黄酮(7-Methoxy-2-methylisoflavone)、芒柄花素(formononetin)、醋栗素(acacetin)等可能是逍遥丸治疗乳腺增生发挥作用的主要活性成分。GO富集分析总共富集到2 328条生物过程,160项分子功能相关,47项细胞组成相关。通路富集分析显示与166条通路相关,涉及AGE-RAGE信号通路、TNF信号通路、IL-17信号通路、TH17细胞分化、流体剪切应力与动脉粥样硬化等信号通路。分子对接验证结果说明关键活性成分与核心靶点均对接良好。

海上浮动平台运动补偿装置的补偿空间分析

在海洋环境中,海上浮动平台在波浪载荷的作用下会对平台上的仪器设备、工程人员等产生不利的影响,甚至引起安全事故。补偿装置可以有效地补偿波浪导致的海上浮动平台的不规则运动,确保设备和人员的安全与工作效率。本文对基于Stewart并联机构的运动补偿装置的平动运动补偿空间进行了研究。文中介绍了基于Stewart机构的运动补偿装置的工作原理和设计流程,对补偿装置进行了运动学分析,给出了计算Stewart平台补偿空间的边界空间搜索方法,对补偿装置的平动运动补偿空间进行了数值求解。本文对海上浮动平台运动补偿装置补偿空间的研究方法可以用于运动补偿装置的设计和分析。

指引导管直接进行罪犯血管造影对急性ST段抬高型心肌梗死患者预后的影响

目的回顾性探讨经桡动脉入径使用指引导管对罪犯血管进行造影对行直接经皮冠状动脉介入治疗(PPCI)的ST段抬高型心肌梗死(STEMI)患者短期预后的影响。方法纳入2016年5月至2017年4月连续在粤北人民医院心血管内科首选经桡动脉入径行PPCI的STEMI患者318例。根据罪犯血管造影耗材分为指引导管组(205例)和造影导管组(113例)。比较两组患者冠状动脉造影完成时间、再灌注完成时间、PPCI完成时间、并发症及30 d主要不良心脑血管事件(MACCE)发生率。结果所有患者均成功完成PPCI。两组患者主动脉内球囊反搏使用率、发病至手术时间、造影完成时间等比较,差异均无统计学意义(均P>0.05);指引导管组患者更换指引导管比例显著大于造影导管组(5.9%比0.9%,P=0.032),而更改动脉入径比例(0.5%比3.5%,P=0.036)、前臂血肿发生率(5.4%比12.4%,P=0.026)、再灌注完成时间[(12.9±10.5)min比(16.3±13.7)min,P=0.025]、PPCI完成时间[(21.8±13.6)min比(27.5±18.7)min,P=0.005]显著小于造影导管组,差异均有统计学意义。两组患者30 d心源性死亡、非致命性再发心肌梗死、靶血管再次血运重建和卒中发生率比较,差异均无统计学意义(均P>0.05),但指引导管组患者总MACCE发生率显著低于造影导管组(6.3%比13.3%,P=0.037)。结论经桡动脉入径使用指引导管对STEMI患者直接进行罪犯血管造影有助于缩短再灌注时间,降低PPCI后30 d的总MACCE发生率。

RP-HPLC-UV法测定半夏泻心汤物质基准中黄芩苷的含量

目的采用高效液相色谱连用紫外检测器检测经典名方半夏泻心汤中黄芩苷含量。方法色谱柱以十八烷基硅烷键合硅胶为填充剂,以0.22%磷酸水为流动相A,甲醇为流动相B,比例为53∶47,流速设置为1mL·min^(-1),检测波长为280nm。结果黄芩苷出峰时间为10min左右,峰形良好且无其他物质干扰,黄芩苷含量在0.26~1.56μg之间呈良好线性关系,得回归方程为:Y=60.999X-1.3235,R^(2)=0.9998。最终确定半夏泻心汤物质基准的黄芩苷每剂含量范围309.23~574.28mg。结论该方法有效简便的测定出半夏泻心汤物质基准中黄芩苷的含量,为经典名方半夏泻心汤的进一步研究与发展奠定基础。

RP-HPLC-UV法测定经典名方金水六君煎中橙皮苷的含量

目的本文采用RP-HPLC-UV法对经典名方金水六君煎中橙皮苷的含量进行测定。方法色谱柱选用十八烷基硅烷键合硅胶柱,以甲醇、HAc和水为流动相,比例为35∶4∶61;UV检测波长为283nm,流速设置为1.0mL·min^(-1),进样量为10μL,柱温设置为30℃。结果橙皮苷含量在2~14μg之间呈良好线性关系,回归方程为:Y=20.474X-0.6305,R2=0.9994,确定金水六君煎物质基准中每克含橙皮苷不得少于5.0mg。结论本文建立的橙皮苷含量测定方法稳定可靠,实验操作简便,为中华传统中医药经典名方的研究与发展奠定基础。

同型半胱氨酸在继发性高血压诊断中的临床价值研究

目的分析同型半胱氨酸(Hcy)在继发性高血压诊断中的临床价值。方法选取80例继发性高血压患者作为研究组,另选取同期行健康体检的健康者80例作为对照组。比较两组血压、同型半胱氨酸水平及研究组不同程度血压患者的同型半胱氨酸水平。结果研究组患者的舒张压(98.28±4.66)mm Hg(1 mm Hg=0.133 kPa)、收缩压(169.55±11.72)mm Hg、同型半胱氨酸(54.02±12.51)μmol/L均明显高于对照组的(79.05±2.73)mm Hg、(116.39±4.76)mm Hg、(4.63±0.52)μmol/L,差异有统计学意义(P<0.05)。血压≥181/111 mm Hg患者的同型半胱氨酸水平高于161~180/101~110 mm Hg及141~160/91~100 mm Hg患者,且血压161~180/101~110 mm Hg患者的同型半胱氨酸水平高于141~160/91~100 mm Hg患者,差异有统计学意义(P<0.05)。结论继发性高血压患者的同型半胱氨酸水平较健康者更高,且血压越高的患者,同型半胱氨酸水平越高。因此同型半胱氨酸的检测可以帮助临床对是否发生继发性高血压,或者对其疾病的严重程度进行预估。

RP-HPLC-UV法测定清心莲子饮基准物质中京尼平苷酸的含量

目的建立RP-HPLC-UV色谱法测定清心莲子饮的基准物质中京尼平苷酸的含量。方法采用依利特C_(18)柱(Sinochrom ODS-BP,4.6mm×200mm,5μm),0.5%的HAc溶液和甲醇进行梯度洗脱,流速控制为1.0mL·min^(-1),在254nm,柱温25℃下进样,进样量为10μL。结果京尼平苷酸的含量与色谱峰面积呈现出良好的线性关系,其线性方程为Y=11.185X+0.065(R^(2)=0.9999)。精密度、重复性和加样回收率等试验RSD均小于3%,平均加样回收率为101.05%,RSD为2.45%。结论本文建立含量测定的方法可行,操作简易,灵敏度高,适于清心莲子饮的物质基准中京尼平苷酸的含量测定,可作为清心莲子饮质量评价的方法。

Comparative analysis of GF-1,HJ-1,and Landsat-8 data for estimating the leaf area index of winter wheat

Using simultaneously collected remote sensing data and field measurements, this study firstly assessed the consistency and applicability of China high-resolution earth observation system satellite 1 （GF-1） wide field of view （WFV） camera, environment and disaster monitoring and forecasting satellite （H J-l） charge coupled device （CCD）, and Landsat-8 opera- tional land imager （OLI） data for estimating the leaf area index （LAI） of winter wheat via reflectance and vegetation indices （VIs）. The accuracies of these LAI estimates were then assessed through comparison with an empirical model and the PROSAIL radiative transfer model. The effects of radiation calibration, spectral response functions, and spatial resolution on discrepancies in the LAI estimates between the different sensors were also analyzed. The results yielded the following observations： （1） The correlation between reflectance from different sensors is relative good, with the adjusted coefficients of determination （R2） between 0.375 to 0.818. The differences in reflectance are ranging from 0.002 to 0.054. The correlation between VIs from different sensors is high with the R2 between 0.729 and 0.933. The differences in the VIs are ranging from 0.07 to 0.156. These results show the three sensors＇ images can all be used for cross calibration of the reflectance and VIs. （2） The four VIs from the three sensors are all demonstrated to be highly correlated with LAI （R2 between 0.703 and 0.849）. The linear models associated with the 2-band enhanced vegetation index （EVI2）, which feature the highest R2 （higher than 0.746） and the lowest root mean square errors （RMSE） （less than 0.21）, were selected to estimate the winter wheat LAI. The accuracy of the estimated LAI from Landsat-8 was the highest, with the relative errors （RE） of 2.18% and an RMSE of 0.13, while the H J-1 was the lowest, with the RE of 2.43% and the RMSE of 0.15. （3） The inversion errors in the different sensors＇ LAI estimates using the PROSAIL model are small. The accuracy of the GF-1 is the highest with the RE of 3.44%, and the RMSE of 0.22, whereas that of the H J-1 is the lowest with the RE of 4.95%, and the RMSE of 0.26. （4） The effects of the spectral response function and radiation calibration for the different sensors are small and can be ignored, but the effects of spatial resolution are significant and must be taken into consideration in practical applications.

Agricultural remote sensing big data:Management and applications

Big data with its vast volume and complexity is increasingly concerned, developed and used for all professions and trades. Remote sensing, as one of the sources for big data, is generating earth-observation data and analysis results daily from the platforms of satellites, manned/unmanned aircrafts, and ground-based structures. Agricultural remote sensing is one of the backbone technologies for precision agriculture, which considers within-field variability for site-specific management instead of uniform management as in traditional agriculture. The key of agricultural remote sensing is, with global positioning data and geographic information, to produce spatially-varied data for subsequent precision agricultural operations. Agricultural remote sensing data, as general remote sensing data, have all characteristics of big data. The acquisition, processing, storage, analysis and visualization of agricultural remote sensing big data are critical to the success of precision agriculture. This paper overviews available remote sensing data resources, recent development of technologies for remote sensing big data management, and remote sensing data processing and management for precision agriculture. A five-layer-fifteen- level （FLFL） satellite remote sensing data management structure is described and adapted to create a more appropriate four-layer-twelve-level （FLTL） remote sensing data management structure for management and applications of agricultural remote sensing big data for precision agriculture where the sensors are typically on high-resolution satellites, manned aircrafts, unmanned aerial vehicles and ground-based structures. The FLTL structure is the management and application framework of agricultural remote sensing big data for precision agriculture and local farm studies, which outlooks the future coordination of remote sensing big data management and applications at local regional and farm scale.

Research advances of SAR remote sensing for agriculture applications: A review

Synthetic aperture radar(SAR) is an effective and important technique in monitoring crop and other agricultural targets because its quality does not depend on weather conditions. SAR is sensitive to the geometrical structures and dielectric properties of the targets and has a certain penetration ability to some agricultural targets. The capabilities of SAR for agriculture applications can be organized into three main categories: crop identification and crop planting area statistics, crop and cropland parameter extraction, and crop yield estimation. According to the above concepts, this paper systematically analyses the recent progresses, existing problems and future directions in SAR agricultural remote sensing. In recent years, with the remarkable progresses in SAR remote sensing systems, the available SAR data sources have been greatly enriched. The accuracies of the crop classification and parameter extraction by SAR data have been improved progressively. But the development of modern agriculture has put forwarded higher requirements for SAR remote sensing. For instance, the spatial resolution and revisiting cycle of the SAR sensors, the accuracy of crop classification, the whole phenological period monitoring of crop growth status, the soil moisture inversion under the condition of high vegetation coverage, the integrations of SAR remote sensing retrieval information with hydrological models and/or crop growth models, and so on, still need to be improved. In the future, the joint use of optical and SAR remote sensing data, the application of multi-band multi-dimensional SAR, the precise and high efficient modeling of electromagnetic scattering and parameter extraction of crop and farmland composite scene, the development of light and small SAR systems like those onboard unmanned aerial vehicles and their applications will be active research areas in agriculture remote sensing. This paper concludes that SAR remote sensing has great potential and will play a more significant role in the various fields of agricultural remote sensing.

Design of a spatial sampling scheme considering the spatial autocorrelation of crop acreage included in the sampling units

Information on crop acreage is important for formulating national food polices and economic planning. Spatial sampling, a combination of traditional sampling methods and remote sensing and geographic information system （GIS） technology, provides an efficient way to estimate crop acreage at the regional scale. Traditional sampling methods require that the sampling units should be independent of each other, but in practice there is often spatial autocorrelation among crop acreage contained in the sampling units. In this study, using Dehui County in Jilin Province, China, as the study area, we used a thematic crop map derived from Systeme Probatoire d＇Observation de la Terre （SPOT-5） imagery, cultivated land plots and digital elevation model data to explore the spatial autocorrelation characteristics among maize and rice acreage included in sampling units of different sizes, and analyzed the effects of different stratification criteria on the level of spatial autocorrelation of the two crop acreages within the sampling units. Moran＇s/, a global spatial autocorrelation index, was used to evaluate the spatial autocorrelation among the two crop acreages in this study. The results showed that although the spatial autocorrelation level among maize and rice acreages within the sampling units generally decreased with increasing sampling unit size, there was still a significant spatial autocorrelation among the two crop acreages included in the sampling units （Moran＇s / varied from 0.49 to 0.89）, irrespective of the sampling unit size. When the sampling unit size was less than 3000 m, the stratification design that used crop planting intensity （CPI） as the stratification criterion, with a stratum number of 5 and a stratum interval of 20% decreased the spatial autocorrelation level to almost zero for the maize and rice area included in sampling units within each stratum. Therefore, the traditional sampling methods can be used to estimate the two crop acreages. Compared with CPI, there was still a strong spatial correlation among the two crop acreages included in the sampling units belonging to each stratum when cultivated land fragmentation and ground slope were used as stratification criterion. As far as the selection of stratification criteria and sampling unit size is concerned, this study provides a basis for formulating a reasonable spatial sampling scheme to estimate crop acreage.

High resolution crop intensity mapping using harmonized Landsat-8 and Sentinel-2 data

An increase in crop intensity could improve crop yield but may also lead to a series of environmental problems, such as depletion of ground water and increased soil salinity. The generation of high resolution(30 m) crop intensity maps is an important method used to monitor these changes, but this is challenging because the temporal resolution of the 30-m image time series is low due to the long satellite revisit period and high cloud coverage. The recently launched Sentinel-2 satellite could provide optical images at 10–60 m resolution and thus improve the temporal resolution of the 30-m image time series. This study used harmonized Landsat Sentinel-2(HLS) data to identify crop intensity. The sixth polynomial function was used to fit the normalized difference vegetation index(NDVI) and enhanced vegetation index(EVI) curves. Then, 15-day NDVI and EVI time series were then generated from the fitted curves and used to generate the extent of croplands. Lastly, the first derivative of the fitted VI curves were used to calculate the VI peaks;spurious peaks were removed using artificially defined thresholds and crop intensity was generated by counting the number of remaining VI peaks. The proposed methods were tested in four study regions, with results showing that 15-day time series generated from the fitted curves could accurately identify cropland extent. Overall accuracy of cropland identification was higher than 95%. In addition, both the harmonized NDVI and EVI time series identified crop intensity accurately as the overall accuracies, producer’s accuracies and user’s accuracies of non-cropland, single crop cycle and double crop cycle were higher than 85%. NDVI outperformed EVI as identifying double crop cycle fields more accurately.

Characterizing Spatial Patterns of Phenology in Cropland of China Based on Remotely Sensed Data

This study used time-series of global inventory modeling and mapping studies （GIMMS） normalized difference vegetation index （NDVI） datasets at a spatial resolution of 8 km and 15-d interval to investigate the spatial patterns of cropland phenology in China. A smoothing algorithm based on an asymmetric Gaussian function was first performed on NDVI dataset to minimize the effects of anomalous values caused by atmospheric haze and cloud contamination. Subsequent processing for identifying cropping systems and extracting phenological parameters, the starting date of growing season （SGS） and the ending date of growing season （EGS） was based on the smoothed NVDI time-series data. The results showed that the cropping systems in China became complex as moving from north to south of China. Under these cropping systems, the SGS and EGS for the first growing season varied largely over space, and those regions with multiple cropping systems generally presented a significant advanced SGS and EGS than the regions with single cropping patterns. On the contrary, the phenological events of the second growing season including both the SGS and EGS showed little difference between regions. The spatial patterns of cropping systems and phenology in Chinese cropland were highly related to the geophysical environmental factors. Several anthropogenic factors, such as crop variety, cultivation levels, irrigation, and fertilizers, could profoundly influence crop phenological status. How to discriminate the impacts of biophysical forces and anthropogenic drivers on phenological events of cultivation remains a great challenge for further studies.

Assimilation of temporal-spatial leaf area index into the CERES-Wheat model with ensemble Kalman filter and uncertainty assessment for improving winter wheat yield estimation

To accurately estimate winter wheat yields and analyze the uncertainty in crop model data assimilations, winter wheat yield estimates were obtained by assimilating measured or remotely sensed leaf area index （LAI） values. The performances of the calibrated crop environment resource synthesis for wheat （CERES-Wheat） model for two different assimilation scenarios were compared by employing ensemble Kalman filter （EnKF）-based strategies. The uncertainty factors of the crop model data assimilation was analyzed by considering the observation errors, assimilation stages and temporal-spatial scales. Overalll the results indicated a better yield estimate performance when the EnKF-based strategy was used to comprehen- sively consider several factors in the initial conditions and observations. When using this strategy, an adjusted coefficients of determination （R2） of 0.84, a root mean square error （RMSE） of 323 kg ha-1, and a relative errors （RE） of 4.15% were obtained at the field plot scale and an R2 of 0.81, an RMSE of 362 kg ha-1, and an RE of 4.52% were obtained at the pixel scale of 30 mx30 m. With increasing observation errors, the accuracy of the yield estimates obviously decreased, but an acceptable estimate was observed when the observation errors were within 20%. Winter wheat yield estimates could be improved significantly by assimilating observations from the middle to the end of the crop growing seasons. With decreasing assimilation frequency and pixel resolution, the accuracy of the crop yield estimates decreased; however, the computation time decreased. It is important to consider reasonable temporal-spatial scales and assimilation stages to obtain tradeoffs between accuracy and computation time, especially in operational systems used for regional crop yield estimates.

Early-season crop type mapping using 30-m reference time series

Early-season crop type mapping could provide important information for crop growth monitoring and yield prediction,but the lack of ground-surveyed training samples is the main challenge for crop type identification.Although reference time series based method(RBM)has been proposed to identify crop types without the use of ground-surveyed training samples,the methods are not suitable for study regions with small field size because the reference time series are mainly generated using data set with low spatial resolution.As the combination of Landsat data and Sentinel-2 data could increase the temporal resolution of 30-m image time series,we improved the RBM by generating reference normalized difference vegetation index(NDVI)/enhanced vegetation index(EVI)time series at 30-m resolution(30-m RBM)using both Landsat and Sentinel-2 data,then tried to estimate the potential of the reference NDVI/EVI time series for crop identification at early season.As a test case,we tried to use the 30-m RBM to identify major crop types in Hengshui,China at early season of 2018,the results showed that when the time series of the entire growing season were used for classification,overall classification accuracies of the 30-m RBM were higher than 95%,which were similar to the accuracies acquired using the ground-surveyed training samples.In addition,cotton,spring maize and summer maize distribution could be accurately generated 8,6 and 8 weeks before their harvest using the 30-m RBM;but winter wheat can only be accurately identified around the harvest time phase.Finally,NDVI outperformed EVI for crop type classification as NDVI had better separability for distinguishing crops at the green-up time phases.Comparing with the previous RBM,advantage of 30-m RBM is that the method could use the samples of the small fields to generate reference time series and process image time series with missing value for early-season crop casification;while,samples collected from multiple years should be futher used so that the reference time series could contain more crop growth conditions.

Effects of meteorological factors on different grades of winter wheat growth in the Huang-Huai-Hai Plain, China

The sown area of winter wheat in the Huang-Huai-Hai（HHH） Plain accounts for over 65% of the total sown area of winter wheat in China. Thus, it is important to monitor the winter wheat growth condition and reveal the main factors that influence its dynamics. This study assessed the winter wheat growth condition based on remote sensing data, and investigated the correlations between different grades of winter wheat growth and major meteorological factors corresponding. First, winter wheat growth condition from sowing until maturity stage during 2011–2012 were assessed based on moderate-resolution imaging spectroradiometer（MODIS） normalized difference vegetation index（NDVI） time-series dataset. Next, correlation analysis and geographical information system（GIS） spatial analysis methods were used to analyze the lag correlations between different grades of winter wheat growth in each phenophase and the meteorological factors that corresponded to the phenophases. The results showed that the winter wheat growth conditions varied over time and space in the study area. Irrespective of the grades of winter wheat growth, the correlation coefficients between the winter wheat growth condition and the cumulative precipitation were higher than zero lag（synchronous precipitation） and one lag（pre-phenophase precipitation） based on the average values of seven phenophases. This showed that the cumulative precipitation during the entire growing season had a greater effect on winter wheat growth than the synchronous precipitation and the pre-phenophase precipitation. The effects of temperature on winter wheat growth varied according to different grades of winter wheat growth based on the average values of seven phenophases. Winter wheat with a better-than-average growth condition had a stronger correlation with synchronous temperature, winter wheat with a normal growth condition had a stronger correlation with the cumulative temperature, and winter wheat with a worse-than-average growth condition had a stronger correlation with the pre-phenophase temperature. This study may facilitate a better understanding of the quantitative correlations between different grades of crop growth and meteorological factors, and the adjustment of field management measures to ensure a high crop yield.

替米沙坦治疗高血压伴阵发性房颤的效果

目的研究并分析替米沙坦治疗高血压伴阵发性房颤的临床效果。方法选取2016年1月~2017年2月本院收治的高血压伴阵发性房颤患者80例作为研究对象,采用随机数字表法分成对照组和观察组,每组40例。对照组采用氨氯地平治疗,观察组采用替米沙坦治疗。比较两组患者的血压、心率、左房内径(LAD)、血清超敏C反应蛋白(hs-CRP)水平和房颤复发率。结果治疗后,两组患者的血压、心率比较,差异均无统计学意义(P>0.05)。观察组患者的LAD、hs-CRP水平均低于对照组(P<0.05)。观察组患者的房颤复发率明显低于对照组(P<0.05)。结论替米沙坦治疗高血压伴阵发性房颤可有效降低患者的血压,缩小其左房内径,降低hs-CRP水平,降低房颤复发率。