外贴液面计

极紫外(EUV) 球面反射镜超抛光基片上的钼/硅多层镀膜13.5nm 下可实现的最大反射设计用于 EUV 光束聚焦应用适用于 HHG 应用的窄通带极紫外(EUV) 球面反射镜具有多层钼/硅镀膜，在 13.5nm 下的反射率大于 60%。它们专为 5o 入射角设计，并用于聚焦非偏振 EUV 激光源。表面粗糙度小于 3?RMS，可最大程度地降低散射。这对 EUV 波长必不可少，因为 EUV 波长的散射比长波长更多. EUV 球面反射镜的通带非常窄，约为 0.5nm，确保只会在高谐波生成 (HHG) 应用中反射 13.5nm 的关注谐波。EUV 球面反射镜的典型应用包括相干衍射成像 (CDI)、EUV 成像和 EUV 纳米加工.注意:每个反射镜均附运行样本的测试数据.产品信息DWL (nm)Dia. (mm)EFL (mm)涂层涂层规格产品编码13.525.40250.00Mo/SiMultilayerTop Layer: SiliconRabs60%@ 13.5nm#11-730

ExoView外泌体全面表征试剂盒外泌体计数、粒径、蛋白表达、蛋白共定位一次完成检测样本类型对细胞培养上清、血浆、血清、尿液、脑脊液、唾液等生物样本中的外泌体直接进行分析捕获抗体种类anti-CD81, anti-CD9, anti-CD63, 同型IgG对照；可自定义单次上样体积35 μl稀释样本重复检测数目3复孔荧光抗体种类CD9（Blue）/ CD81（Green）/ CD63（Red）实验原理① 35 μL外泌体样品滴加在芯片上孵育；② 预先包被的抗体特异结合外泌体表面蛋白以捕获外泌体；③ 再使用荧光抗体特异性标记需要表征的标记物；④ 后用ExoView R100检测外泌体粒径、计数、蛋白表达（CD9，CD81，CD63等）及共定位。检测流程产品类别产品货号产品名称EV-TETRA-C人外泌体检测试剂盒EV-TETRA-P人血浆外泌体检测试剂盒EV-TETRA-M2鼠外泌体检测试剂盒EV-TETRA-C-CAR人外泌体内容物检测试剂盒EV-TETRA-P-CAR人血浆外泌体内容物检测试剂盒EV-TC-FLEX自由捕获人外泌体检测试剂盒EV-TP-FLEX自由捕获人血浆外泌体检测试剂盒EV-TC-FLEX-CAR自由捕获人外泌体内容物检测试剂盒EV-TP-FLEX-CAR自由捕获人血浆外泌体内容物检测试剂盒EV-TM-FLEX自由捕获鼠外泌体检测试剂盒EV-TM-FLEX-CAR自由捕获鼠外泌体内容物检测试剂盒EV-FLEX-2自由捕获外泌体检测试剂盒EV-FLEX-2 -CAR自由捕获外泌体内容物检测试剂盒EV-CTETRA-1/2/3人外泌体检测试剂盒+1/2/3个自定义捕获抗体EV-CTETRA-1/2/3-CAR人外泌体内容物检测试剂盒+1/2/3个自定义捕获抗体EV-CUST-1/2/3/4/5/6自定义1/2/3/4/5/6抗体捕获外泌体检测试剂盒EV-CUST-1/2/3/4/5/6-CAR自定义1/2/3/4/5/6抗体捕获外泌体内容物检测试剂盒试剂盒特点特异性捕获芯片上可包被多达6种捕获抗体，特异性捕获含特定蛋白标记物的外泌体。阳性外泌体计数芯片捕获外泌体后，可通过SP-IRIS技术直接检测样品中外泌体的数量。单个外泌体蛋白共定位分析检测每个外泌体的荧光信号并进行统计，可获得荧光共定位信息，用于分析样品中不同表型外泌体的比例（如右图所示）。无需纯化使用抗体捕获模式，防止样品中杂质影响结果，可直接检测血液、尿液和细胞培养液中的外泌体，未纯化样品的测量结果与纯化后基本一致（如右图所示）。粒径分辨率高高精度SP-IRIS技术，可检测≥50 nm的外泌体，测量结果与电子显微镜检测结果基本一致，并统计生成外泌体的粒径分布结果（如右图所示）。可检测外泌体内容物试剂盒配套相应的穿膜剂，可穿透外泌体并对外泌体内容物进行染色并检测，未穿膜时只能检测到跨膜蛋白CD9的荧光信号，穿膜后即可检测到外泌体内容物Syntenin的表达（如右图所示）。测试数据外泌体荧光数量统计外泌体粒径检测荧光强度与粒径关系荧光共定位分析发表文章• Andras Saftics.(2021) Data evaluation for surface-sensitive label-free methods to obtain real-time kinetic and structural information of thin films: A practical review with related software packages. Advances in Colloid and Interface Science. • Kyoung-Won Ko.(2021) Integrated Bioactive Scaffold with Polydeoxyribonucleotide and Stem-Cell-Derived Extracellular Vesicles for Kidney Regeneration. ACS Nano. • Tanina Arab. (2021) Characterization of extracellular vesicles and synthetic nanoparticles with four orthogonal single‐particle analysis platforms. Journal of Extracellular Vesicles. • Niaz Z.Khan.(2021) Spinal cord injury alters microRNA and CD81+ exosome levels in plasma extracellular nanoparticles with neuroinflammatory potential. Brain, Behavior, and Immunity. • Dario Brambilla. (2021) EV Separation: Release of Intact Extracellular Vesicles Immunocaptured on Magnetic Particles. Analytical Chemistry. • Enkhtuya Radna. (2021) Extracellular vesicle mediated feto-maternal HMGB1 signaling induces preterm birth. Lab on a Chip. • Li, M., Soder. (2021) WJMSC‐derived small extracellular vesicle enhance T cell suppression through PD‐L1. Journal of Extracellular Vesicles. • Crescitelli, R. (2021) Isolation and characterization of extracellular vesicle subpopulations from tissues. Nature protocols. • Berger, A. (2021). Local administration of stem cell-derived extracellular vesicles in a thermoresponsive hydrogel promotes a pro-healing effect in a rat model of colo-cutaneous post-surgical fistula. Nanoscale. • Vidal, M. (2020) Exosomes and GPI-anchored proteins: Judicious pairs for investigating biomarkers from body fluids. Advanced drug delivery reviews. • K Cho, H Kook.(2020)Study of immune-tolerized cell lines and extracellular vesicles inductive environment promoting continuous expression and secretion of HLA-G from semiallograft immune tolerance during pregnancy. Journal of Extracellular Vesicles. • Maximillian A. Rogers.(2020)Annexin A1–dependent tethering promotes extracellular vesicle aggregation revealed with single–extracellular vesicle analysis. Cell Biology. • Annette M. Marleau.(2020)Targeting tumor-derived exosomes using a lectin affinity hemofiltration device. Cancer Research. • Alessandro Gori.(2020)Membrane-Binding Peptides for Extracellular Vesicles On-Chip Analysis. Journal of Extracellular Vesicles. • Rossella Crescitelli.(2020)Subpopulations of extracellular vesicles from human metastatic melanoma tissue identified by quantitative proteomics after optimized isolation. Journal of Extracellular Vesicles. • Maria S. Panagopoulou.(2020) Phenotypic analysis of extracellular vesicles: a review on the applications of fluorescence. Journal of Extracellular Vesicles.• WeiYan.(2020) Immune Cell-Derived Exosomes in the Cancer-Immunity Cycle. Trends in Cancer. • Daniel Bachurski. (2019) Small RNA Sequencing across Diverse Biofluids Identifies Optimal Methods for exRNA Isolation. Cell.用户单位外泌体检测流程：仅需7步实现外泌体快速检测

【产品名称】通用名称：3%氯化钠三糖铁琼脂斜面英文名称：3%NAClTryptic Sugar Iron Agar【产品编号与包装规格】产品编号产品类型包装规格022543C管装成品10mL×20支/盒【产品用途】用于副溶血性弧菌的生化反应。【检验原理】蛋白胨、牛肉膏粉提供氮源、维生素、矿物质；乳糖、葡萄糖、蔗糖为可发酵糖类，其产酸时通过酚红指示剂测出，酸性呈黄色，碱性呈红色；硫代硫酸钠可被某些细菌还原为硫化青，与硫酸亚铁中的铁盐生成黑色硫化铁；较高含量的氯化钠维持弧菌均衡的渗透压；琼脂是培养基的凝固剂。【配方成分】配方（每升）含量蛋白胨20.0g牛肉膏粉3.0g乳糖10.0g蔗糖10.0g葡萄糖1.0g氯化钠30.0g硫酸亚铁0.5g硫代硫酸钠0.5g琼脂12.0g酚红0.024g蒸馏水1000mL最终pH7.4±0.2【使用方法】拆开包装即可使用。【质量控制】下列质控菌株接种后于35～37℃培养24h，观察结果如下表：质控菌株及编号特征性反应副溶血性弧菌ATCC17802斜面变红，底部变黄溶藻弧菌ATCC33787斜面和底部均变黄【储存条件与保质期】2~25℃，避光保存，有效期见产品标签。【注意事项】1、一次性固体培养基置于冰箱冷藏保存需与存放容器冷凝管保持一定距离以避免冻损坏。产品多次在低温与常温之间变更会引起琼脂的泌水，属于正常现象。使用前应平衡至室温且尽量在无菌干燥箱中预干燥。2、质检报告可以登录环凯培养基网站，打开“下载中心”页面，输入产品批号下载。【废物处理】检测之后带菌物品置于121℃下高压灭菌30分钟后处理。【执行标准】Q/HKSJ 03-2011 广东环凯微生物科技有限公司企业标准 普通微生物培养基【参考文献】GB 4789 .7-2013 食品安全国家标准 副溶血性弧菌检验