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伽玛射线对生长,产量和产量成分的影响
*相应的电子邮件:saadedan91@gmail.com摘要在2020-2021季期间,在Al-Alam区\ Sallahiddin省的农业领域进行了一个现场实验,以研究由于γ射线的产生亚麻遗传学作物的遗传变异。The study factors included four levels of gamma rays, which were 0, 9, 18 and 27 Gy and six genotypes of the flax crop, which were Sakha1, Sakha2, Sakha3, Giza8, Syrian and Poloni, use a completely randomized block design with split plot system and was used three replications, traits studied were Duration to 50% flowering and Duration of days to maturity, Plant height, Leaves ratio,植物分支的数量,种子数量,1000种种子重量,植物产量和种子产量。The results of the study indicated that gamma rays had a significant effect on all studied traits, comparison treatment gave a lower value from the number of days to flowering 50% of plants and days to maturity (110.24) and (155.05) days, respectively, while the plants irradiated with the level 9 Gy recorded a significant superiority in the percentage of leaves (21.46) %, while the non-irradiated plants outperformed in其余的研究特征。基因型SAKHA1在营养分支数量(3.63)分支-1,每植物的胶囊数量(54.35)胶囊植物-1,单个植物产量(2.22)GM植物-1和种子产量(433.63)kg ha -1中给出了最高平均平均值。至于相互作用,它通过非辐照的Sakha1基因型具有重要意义,该基因型具有最高的每植物胶囊数量的特征,人均种子数量,个体植物产量和总种子产量(62.22)胶囊植物-1 9.96种子胶囊-1 9.96种子胶囊-1(2.89)g植物-1(2.89)g植物-1(578.60)。
氧化锌的聚合物封装
3。RESULTS......................................................................................52 3.1.ZnO nanoparticles and their nanohybrids ..............................52 3.1.1.晶体结构......................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................... 52 3.1.2。Nanostructures and morphology.......................................56 3.1.3.Chemical bonding............................................................64 3.1.4.X射线光电子光谱.............................................................................................................. 67 3.1.5。拉曼光谱法..................................................................................................................... 72 3.1.6。频段间隙........................................................................................................................................................... 75 3.1.7。光致发光发射光谱............................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................... 77 3.2。ZnO nanorods ........................................................................83 3.2.1.结晶结构........................................................................................................................................................................................................................................................................................... 83 3.2.2。Morphology......................................................................84 3.2.3.光学特性......................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................... 86 3.2.4。Electrical properties studied by I-V and I-t measuremesnts............................................................................88 3.3.Photodiodes............................................................................93 3.3.1.形态..................................................................................................................................................................................................................................................................................................................................................................... 93 3.3.2。I-V characteristics in dark.................................................94 3.3.3.理想因素计算........................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................... 95 3.3.4。I-V辐射下的I-V特征................................................................................................................................................................................................................................................................................. 95 3.3.5。I-t characteristics: UV on/off cycles...................................97 3.3.6.Figures of merit................................................................98
使用移植后移植术后移植后同种异体干细胞移植合并症指数的影响
摘要背景:已经开发了三种不同的评分系统来评估同种异性造血干细胞移植(Allo-HSCT)的移植前合并症:造血细胞移植特异性合并症指数,合并症/年龄指数,增强的合并/年龄段。All were devised to predict overall survival (OS) and disease-free survival (DFS) survivals and non-relapse mortality (NRM) in patients receiving HLA-matched Allo-HSCT, but their performance has scarcely been studied in the haploidentical Allo-HSCT setting with post-transplant cyclophosphamide, a procedure in con- stant expansion worldwide.方法:为了解决这个问题,在四个不同中心的223名接受单倍同化Allo-HSCT治疗的患者中检查了它们对生存和NRM的影响。
急性心肌梗塞的心源性休克的预测因素和结果
方法:这是一项回顾性,比较和分析性的单中心研究,包括在孟加拉国哈比根郡250 Bed District Sadar医院手术部门的319名ACS患者。在入院时出示CS的患者被排除在研究之外。该人群分为两组:冲击组患者最终发展了院内CS和没有冲击组,但我们比较了总体患者特征和结果。Studied characteristics included patient demographics (age, sex), medical history (cardiovascular risk factors and comorbidities), clinical status including the presence of heart failure (HF), electrocardiogram data, laboratory findings such as high-sensitivity troponin and glomerular filtration rate (eGFR), echocardiographic findings mainly left ventricular ejection fraction (LVEF) and left ventricular hypertrophy (LVH)和冠状动脉血管造影期间发现的病变。
Omnipod Pods药物数量管理政策 - 每天
•Omnipod 5自动胰岛素输送系统旨在用于胰岛素的SC递送,设置和可变率(基础和推注),用于在需要胰岛素的人中管理DM。3,它适用于1型DM≥2岁的患者。Omnipod 5能够可靠,安全地与兼容,数字连接的设备(包括自动胰岛素剂量软件)进行可靠,以接收,执行和确认这些设备的命令。•Omnipod GO旨在在24小时内以24小时(72小时)的成人在24小时的时间内以预设的基础速率进行SC输注2型DM。4剂量的Omnipod,Omnipod Dash和Omnipod 5系统,应每72小时或输送200个U-100胰岛素(以先到者为准)的200单位U-100胰岛素至少更换一次POD。由于POD本身或设备可能出现问题, 1-3 POD也可能需要更频繁地更换。 胰岛素的类型还可以决定需要更改POD的频率。 Omnipod Go Pods递送胰岛素连续以固定的每日基础速率持续长达72小时。 4 The Omnipod and Omnipod DASH systems have been studied and found to be safe with the following U-100 rapid-acting insulins: NovoLog ® (insulin aspart), Fiasp ® (insulin aspart), Humalog ® (insulin lispro), Lyumjev ™ (insulin lispro-aabc), Apidra ® (insulin glulisine), or Ambelog®(胰岛素LISPRO)。 Novolog,Fiasp,Humalog,Lyumjev和Ambelog与最多使用72小时(3天)相兼容,而Apidra则兼容最多48小时(2天)。 1,21-3 POD也可能需要更频繁地更换。胰岛素的类型还可以决定需要更改POD的频率。Omnipod Go Pods递送胰岛素连续以固定的每日基础速率持续长达72小时。4 The Omnipod and Omnipod DASH systems have been studied and found to be safe with the following U-100 rapid-acting insulins: NovoLog ® (insulin aspart), Fiasp ® (insulin aspart), Humalog ® (insulin lispro), Lyumjev ™ (insulin lispro-aabc), Apidra ® (insulin glulisine), or Ambelog®(胰岛素LISPRO)。Novolog,Fiasp,Humalog,Lyumjev和Ambelog与最多使用72小时(3天)相兼容,而Apidra则兼容最多48小时(2天)。1,2
quantum-spin-wave-excited-from-a-cr-dy-single-molecule- ...
INTRODUCTION Molecules could become tiny magnets if the spin centers are judiciously chosen and placed in a proper way. 1 Such molecules are widely studied and known as single-molecule magnets (SMMs) and widely perceived as a new generation of nanosized information carriers for highly miniaturized spintronics and quantum computing processors. 2-5 According to the number of the spin centers SMMs can be basically divided into two groups, namely the single-ion magnets 6-12 and the multi-nuclear spin clusters. 13-18 The former is latterly emerged as Ishikawa discovered that the single lanthanide ion could generate strong uniaxial magnetic anisotropy which significantly damps the relaxation of the magnetic moment. 6 The latter actually ignited the starter of the SMM story signaled by the discovery of the magnet-type behavior of a mixed-valent manganese cluster {Mn 12 } in 1993. 13 Due to the multi spin center nature of the latter such class of molecular magnets has developed many interesting branches. Coordination cluster with spin-wave excitations is one of the kinds. 19
报告审议结果
Stimulation Reaction studied JAK involved IC 50 (n mol/L) Filgotinib GS-829845 IL-6 STAT1 phosphorylation JAK1 629-1,180 11,850-11,917 IL-2 STAT5 phosphorylation JAK1/JAK3 1,789 19,626 IFNα STAT1 phosphorylation JAK1/TYK2 506-1,127 15,423 IL-6 STAT3磷酸化JAK1/JAK3/TYK2 2,632-3,410 28,860 28,860 IL-2IFNγ产生JAK1/JAK1/JAK3 316未研究GM-CSF Stat5 STAT5 STAT5 STAT5磷酸化JAK2 JAK2 JAK2 JAK2 JAK2 17,453> 100,000 TPO STAT3 pPO STAT3 PHOST3 PRITHING JAKIND jAK2 pHoSTICAING 2 pHoSTIRE-6 NOT DECTISUL-6 NOT STRITUR-6 NOT STINIT-NOT STINIT-NOT STRITUL-6 NOT COTICUL-6 NOT STRITUL-6( 30或750 ng/ml); IL-2(4或10 ng/ml); IFNα(5 ng/ml或1,000 U/ml); GM-CSF(20 pg/ml);血栓蛋白(TPO)(30 ng/ml)
DNA折纸铰链融合的自我修复水凝胶
Figure 1 – Schematic of wound healing in humans ........................................................ 3 Figure 2 – Schematic on DNA hairpin-based shape memory hydrogel............................ 5 Figure 3 – Schematics on how different studied self-healing systems work..................... 7 Figure 4 – DNA structure and the complementary base-pairing system ........................ 10 Figure 5 – Examples of DNA nanotechnology构造........................................................................................................................................................................................................................................................................................................................................................................................................................................................... 13图7 - 3D DNA折纸曲柄滑块结构.................................................to attach the DNA oligonucleotide crosslinks to the pAA chain ........................................................................................ 17 Figure 10 – Schematic illustrating how a free radical polymerization progresses........... 18 Figure 11 – DNA hairpin-dependent expansion of the pAA hydrogels in the 2017 study by Schulman et al................................................................................................................................................................................................................................................................................ 19图12 - PAA聚合反应的示意图............................................................................................................... 60分钟后的水凝胶形成.... 28图16 - 优化的PAA-SSDNA水凝胶............................................................................................................................................................................................... 29图17 - 对PAA凝胶优化的不同冷却设置的定性分析结果的结果.................................................................................................................................................................................................................................................................................反应混合物中存在的ssdna ................................................................................................................................................................................................................................................................................................................................................................................................................................. 30
糖尿病患者(II型)和非...
亚洲化学科学杂志2(1):1-9,2017;第31945条第31945条。Sciendomain国际www.sciencedomain.org solenostemon onerostachyus叶提取物作为酸性培养基okon U.Abakedi 1* 1酸性媒介中的铝腐蚀的生态友好抑制剂。1017,尼日利亚Uyo。 作者的贡献唯一的作者设计,分析和解释和准备了手稿。 文章信息doi:10.9734/ajocs/2017/31945编辑(s):(1)Zygadlo Julio Alberto,阿根廷科尔多瓦国立大学化学教授。 审稿人:(1)Mahima Srivastava,D.B.S。 (PG)大学,H.N.B。 印度加尔瓦尔大学。 (2)P。Manjula,APA妇女学院(折磨于特蕾莎修女,)印度泰米尔纳德邦Kodaikanal。 (3)印度纳纳迪乔德布尔国立大学的穆斯塔法·巴拉拉贝(Mustapha Balarabe)。 (4)印度卡纳塔克邦班加罗尔工程学院的Abida Begum。 Complete Peer review History: http://www.sciencedomain.org/review-history/18286 Received 31 st January 2017 Accepted 27 th February 2017 Published 21 st March 2017 ABSTRACT The inhibitory effect of Solenostemon monostachyus leaf extract on aluminium corrosion in hydrochloric acid solution was studied using weight loss, thermometric and hydrogen evolution methods. 获得的结果表明,Solenostemon sonostachyus叶提取物在HCl溶液中充当铝腐蚀的良好抑制剂。 抑制效率随着提取物浓度和温度的升高而增加。1017,尼日利亚Uyo。作者的贡献唯一的作者设计,分析和解释和准备了手稿。文章信息doi:10.9734/ajocs/2017/31945编辑(s):(1)Zygadlo Julio Alberto,阿根廷科尔多瓦国立大学化学教授。审稿人:(1)Mahima Srivastava,D.B.S。(PG)大学,H.N.B。 印度加尔瓦尔大学。 (2)P。Manjula,APA妇女学院(折磨于特蕾莎修女,)印度泰米尔纳德邦Kodaikanal。 (3)印度纳纳迪乔德布尔国立大学的穆斯塔法·巴拉拉贝(Mustapha Balarabe)。 (4)印度卡纳塔克邦班加罗尔工程学院的Abida Begum。 Complete Peer review History: http://www.sciencedomain.org/review-history/18286 Received 31 st January 2017 Accepted 27 th February 2017 Published 21 st March 2017 ABSTRACT The inhibitory effect of Solenostemon monostachyus leaf extract on aluminium corrosion in hydrochloric acid solution was studied using weight loss, thermometric and hydrogen evolution methods. 获得的结果表明,Solenostemon sonostachyus叶提取物在HCl溶液中充当铝腐蚀的良好抑制剂。 抑制效率随着提取物浓度和温度的升高而增加。(PG)大学,H.N.B。印度加尔瓦尔大学。 (2)P。Manjula,APA妇女学院(折磨于特蕾莎修女,)印度泰米尔纳德邦Kodaikanal。 (3)印度纳纳迪乔德布尔国立大学的穆斯塔法·巴拉拉贝(Mustapha Balarabe)。 (4)印度卡纳塔克邦班加罗尔工程学院的Abida Begum。 Complete Peer review History: http://www.sciencedomain.org/review-history/18286 Received 31 st January 2017 Accepted 27 th February 2017 Published 21 st March 2017 ABSTRACT The inhibitory effect of Solenostemon monostachyus leaf extract on aluminium corrosion in hydrochloric acid solution was studied using weight loss, thermometric and hydrogen evolution methods. 获得的结果表明,Solenostemon sonostachyus叶提取物在HCl溶液中充当铝腐蚀的良好抑制剂。 抑制效率随着提取物浓度和温度的升高而增加。印度加尔瓦尔大学。(2)P。Manjula,APA妇女学院(折磨于特蕾莎修女,)印度泰米尔纳德邦Kodaikanal。(3)印度纳纳迪乔德布尔国立大学的穆斯塔法·巴拉拉贝(Mustapha Balarabe)。(4)印度卡纳塔克邦班加罗尔工程学院的Abida Begum。Complete Peer review History: http://www.sciencedomain.org/review-history/18286 Received 31 st January 2017 Accepted 27 th February 2017 Published 21 st March 2017 ABSTRACT The inhibitory effect of Solenostemon monostachyus leaf extract on aluminium corrosion in hydrochloric acid solution was studied using weight loss, thermometric and hydrogen evolution methods.获得的结果表明,Solenostemon sonostachyus叶提取物在HCl溶液中充当铝腐蚀的良好抑制剂。抑制效率随着提取物浓度和温度的升高而增加。抑制效率随着提取物浓度和温度的升高而增加。已经提出了化学吸附机制,以吸附叶提取物上铝表面。热力学参数表明,提取物在金属表面上的吸附是吸热和自发的。在铝表面上的索雷诺斯尼斯犬叶提取物的吸附使弗朗迪希的吸附等温线吸附。关键字:腐蚀抑制; Solenostemon Monostachyus;铝; Freundlich等温;化学孔;减肥;温度计;氢的进化。
各种化妆品中番石榴叶提取物的潜在优势...
摘要:富含生物活性化合物的番石榴叶提取物提供了许多适合整合到美容配方中的治疗益处。本评论探讨了番石榴提取物在化妆品应用中的多方面潜力。番石榴叶(P. guajava L.)包含许多生物活性化合物,在保持健康皮肤方面起着重要作用。The leaves of the guava plant have been studied for their health benefits which are attributed to their plethora of phytochemicals such as quercetin, avicularia, apigenin, guaijaverin, kaempferol, hyperin, myricetin, catechin, epicatechin, chlorogenic acid, gallic acid, epigallocatechin gallate, and caffeic acid.在这篇综述中,我们首先概述了化妆品中草药成分的好处以及番石榴叶提取物的健康益处。我们提供有关皮肤护理产品中番石榴叶提取物的抗氧化剂,抗菌和治疗痤疮的潜在影响的信息。然后,我们采用番石榴叶提取物在口腔护理产品中的作用,以进行抗菌活性,防止口腔疾病和护发产品消除头皮屑,减少头发掉落等。