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- Apogee
- Apogee A50
- 2026年01月04日
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科研产品,不能用于临床
大部分流式细胞仪主要针对哺乳动物细胞而设计,但是细菌不同,它们的体积比哺乳类的细胞小三个数量级,因此产生的光学信号非常微弱。
Apogee 公司的A50系列突破传统流式细胞仪,具有无法匹敌的灵敏度(<100nm)、光散射分辨率(20nm),能检测到比普通细菌小两个数量级的微生物,在微生物检测和循环微粒检测领域处于领先地位。仅用光散射,细菌、古生菌、循环微粒以及大部分病毒都能被精确检测。
安全、简单、可靠
· 专注——只从事分析型流式细胞仪的研制、开发
· 专业——操作简单、结果可靠
· 专长——聚焦经济型流式细胞仪,小巧、轻便
轻便、小巧、灵活
· 系统内部PC 配置Windows XP 操作系统,只需外接显示器、键盘、鼠标即可。
· Apogee 开、关机方便,与普通电脑开关机无异,开机即可使用,不需预热时间。
· 机身轻巧、方便移动。
· 如需在室外使用,可选配带触屏装置的流式细胞仪。
更高的质量、更好的技术
·灵敏度100nm
·分辨率20nm
·样品流速1.39-200ul/min多档速度可调
·快速的数据获取性能,可高达100,000 events/sec
·宽泛的样品检测范围,102-109cell/ml
·高自动化、强灵活性
·支持EP管、流式管检测, 鞘液为去离子水,没有任何后期耗材费用
·内置电脑和Windows操作系统 (只需要配置显示器、鼠标和键盘即可)
·内置注射泵喷嘴,无需担忧样本堵塞管路问题(可放心上样浑浊的环境样品等)
·可升级,支持多孔板测读
·病毒、古生菌、细菌 循环微粒 市场上的流式细胞仪通常用RNA或DNA染色的方法来检测体积较大的病毒,小体积病毒的散射光信号低下,难以捕捉到。而Apogee 在这领域的散射光和荧光检测处于领先地位,在科研领域让病毒、古生菌、细菌、循环微粒检测变得非常容易。
·食品和饮料工艺开发和监测(如益生菌,发酵)
·污水厂的监测和建模
·水质的快速评价
·快速细胞计数,快速DNA含量、细胞膜完整性、细胞内活性测定,等……
·遗传学研究(如古生菌、细菌细胞周期研究)
·海洋生物学(如浮游生物群落分析)
·病原体快速检测
·免疫学(如淋巴细胞表型分析)
·DNA分析
·精子分析
·生物量评估
·……
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- 作者
- 内容
- 询问日期
文献和实验Brain, Behavior, and Immunity
Volume 123, January 2025, Pages 422-441
View Paper
Zhucheng Lin, Xuan Luo, Jason R. Wickman, Deepa Reddy, Jason T. DaCunza, Richa Pande, Yuzhen Tian, Ezgi E. Kasimoglu, Vivian Triana, Jingyun Lee, Cristina M. Furdui, Desmond Pink, Ahmet Sacan, Seena K. Ajit
Inflammatory pain resolution by mouse serum-derived small extracellular vesicles
2025
Alzheimer's Dement. 2024;1-13
View paper
Dayarathna T, Roseborough AD, Gomes J, et al.
Nanoscale flow cytometry-based quantification of blood-based extracellular vesicle biomarkers distinguishes MCI and Alzheimer's disease
2024
Cytometry. 2023;103(8):670-83
View paper
Pink D, Basu A, Wong M, Pham D, Valencia J, Triana V, et al.
Antibody titrations are critical for microflow cytometric analysis of extracellular vesicles
2023
Neurobiology of Disease
Volume 177, February 2023, 106001
View paper
A.D. Roseborough, Y. Zhu, L. Zhao, S.R. Laviolette, S.H. Pasternak, S.N. Whitehead
Fibrinogen primes the microglial NLRP3 inflammasome and propagates pro-inflammatory signaling via extracellular vesicles: Implications for blood-brain barrier dysfunction
2023
Journal of Neuroinflammation
View paper
A.D.Roseborough, S.J.Myers, R.Khazaee, Y. Zhu, L.Zhao, E.Iorio, F.M.Elahi, S. H.Pasternak and S.N.Whitehead
Plasma derived extracellular vesicle biomarkers of microglia activation in an experimental stroke model
2023
Neurobiology of Disease 177 (2023) 106001
View paper
A.D. Roseborough, Y. Zhu, L. Zhao, S.R. Laviolette, S.H. Pasternak, S.N. Whitehead
Fibrinogen primes the microglial NLRP3 inflammasome and propagates pro-inflammatory signaling via extracellular vesicles: Implications for blood-brain barrier dysfunction
2023
ACS Earth Space Chem
View paper
Serge Nader, Alexandre Baccouche, Fiona Connolly, Maya Abou-Ghanem, Sarah A. Styler, John D. Lewis, Desmond Pink, and Sheref S. Mansy
Model Atmospheric Aerosols Convert to Vesicles upon Entry into Aqueous Solution
2022
Mol Oncol. 2022 Dec 15
DOI: 10.1002/1878-0261.13362
View paper
Robert J Paproski , Desmond Pink , Deborah L Sosnowski , Catalina Vasquez, John D Lewis
Building predictive disease models using extracellular vesicle microscale flow cytometry and machine learning
2022
PubMed PMID: 36408626
DOI: 10.1042/BSR20222185
View paper
Roberto Villalobos-Labra , Ricky Liu , Floor Spaans , Tamara Saez , Anita Quon, Michael Wong , Desmond Pink , John Lewis , Manu Vatish , Sandra T Davidge, Christy-Lynn M Cooke
Placenta-Derived Extracellular Vesicles from Preeclamptic and Healthy Pregnancies Impair ex vivo Vascular Endothelial Function
2022
Nanoscale, 2022, 14, 9781
Yohan Kim, Edwin van der Pol, Ali Arafa, Ishwor Thapa, Cameron J. Britton, Jorgena Kosti, Siyang Song, Vidhu B. Joshi, Ree M. Erickson, Hesham Alie, Fabrice Lucien
Calibration and standardization of extracellular vesicle measurements by flow cytometry for translational prostate cancer research
2022
Biomedicines 2021, 9, 124.
View paper
Jaco Botha, Haley R. Pugsley, Aase Handberg
Conventional, High-Resolution and Imaging Flow Cytometry: Benchmarking Performance in Characterisation of Extracellular Vesicles
2021
Platelets31.2 (2020): 206-214.
Rosinska, Justyna, et al.
"Effect of acetylsalicylic acid intake on platelet derived microvesicles in healthy subjects."
2020
PLoS ONE 15(8)
Palviainen M, Saraswat M, Varga Z, Kitka D, Neuvonen M, Puhka M, et al.
Extracellular vesicles from human plasma and serum are carriers of extravesicular cargo. Implications for biomarker discovery.
2020
Cells, 2020
J Karkowska-Kuleta, K Kulig, E Karnas, E Zuba-Surma
Characteristics of Extracellular Vesicles Released by the Pathogenic Yeast-Like Fungi Candida glabrata, Candida parapsilosis and Candida tropicalis
2020
bioRxiv (2020).
Cooper, Tyler T., et al.
"Ultrafiltration Segregates Tissue Regenerative Stimuli Harboured Within and Independent of Extracellular Vesicles."
2020
Gastroenterology (2020)
Dasgupta D et al.
IRE1A Stimulates Hepatocyte-derived Extracellular Vesicles That Promote Inflammation in Mice With Steatohepatitis
2020
Front. Oncol., 04 June 2020
L. G. Rikkert et al.
Cancer-ID: Toward Identification of Cancer by Tumor-Derived Extracellular Vesicles in Blood.
2020
Brain. 2020 May 1;143(5):1476-1497.
Min Guo et al.
Microglial Exosomes Facilitate synuclein Transmission in Parkinson's Disease.
2020
PLoS ONE 15(6): e0233443.
Rikkert LG, de Rond L, van Dam A, van Leeuwen TG, Coumans FAW, de Reijke TM, et al.(2020)
Detection of extracellular vesicles in plasma and urine of prostate cancer patients by flow cytometry and surface plasmon resonance imaging.
2020
Platelets, 2020, 31(1): 26-32.
Gasecka A, Nieuwland R, Budnik M, et al.
Randomized controlled trial protocol to investigate the antiplatelet therapy effect on extracellular vesicles (AFFECT EV) in acute myocardial infarction[J].
2020
bioRxiv, 2020
Maia J, Batista S, Couto N, et al.
Population Analysis of Extracellular Vesicles in Microvolumes of Biofluids[J].
2020
Neuro-Oncology, Volume 22, Issue 7, July 2020, Pages 967-978
Benjamin T. Himes et al.
The role of extracellular vesicles and PD-L1 in glioblastoma-mediated immunosuppressive monocyte induction.
2020
Mitochondrion 8 August 2020
Olivia R.Stephens et al.
Characterization and origins of cell-free mitochondria in healthy murine and human blood.
2020
Cell Death Dis 11, 677 (2020).
Gidlof, O., Bader, K., Celik, S. et al.
Inhibition of the long non-coding RNA NEAT1 protects cardiomyocytes from hypoxia in vitro via decreased pri-miRNA processing.
2020
BMC Ophthalmology volume 20, Article number: 233 (2020)
Zhong-Fang Yuan et al.
MicroRNA-182-5p protects human lens epithelial cells against oxidative stress-induced apoptosis by inhibiting NOX4 and p38 MAPK signalling.
2020
Colloids and Surfaces B: Biointerfaces (2020)
Hou Y-chen, Li J-an, Zhu S-jie, Cao C, Tang J-nan, Zhang J-ying, Guan S-kang
Tailoring of cardiovascular stent material surface by immobilizing exosomes for better pro-endothelialization function
2020
View paper
Desmond Pink, Michael Wong, Diana Pham, Renjith Pillai , Leanne Stifanyk, Sylvia Koch, Rebecca Hiebert, Oliver Kenyon, John Lewis
Performance Qualification for Micro Flow Cytometers: Understanding technical limitations to improve your research
Jul-20
THE JOURNAL OF UROLOGY 1 Apr 2019
Fabrice Lucien-Matteoni et al.
NEXT-GENERATION LIQUID BIOPSIES USING EXTRACELLULAR VESICLE DETECTION BY NANOSCALE FLOW CYTOMETRY.
2019
Journal of hepatology, 2019, 71(6): 1193-1205.
Guo Q, Furuta K, Lucien F, et al.
Integrin 1-enriched extracellular vesicles mediate monocyte adhesion and promote liver inflammation in murine NASH[J].
2019
ournal of extracellular vesicles, 2019, 8(1): 1643671
de Rond L, Libregts S, Rikkert L G, et al.
Refractive index to evaluate staining specificity of extracellular vesicles by flow cytometry[J].
2019
Journal of extracellular vesicles, 2019, 8(1): 1629865
Zeng Y, Yao X, Liu X, et al.
Anti-angiogenesis triggers exosomes release from endothelial cells to promote tumor vasculogenesis[J].
2019
Journal of diabetes research, 2019
Hohendorff J, Drozdz A, Borys S, et al.
Effects of Negative Pressure Wound Therapy on Levels of Angiopoetin-2 and Other Selected Circulating Signaling Molecules in Patients with Diabetic Foot Ulcer[J].
2019
率 英国Apogee公司的A50-Micro突破传统流式细胞仪的检测极限,优化的光学模块和优异的散射光检测能力使得A50-Micro具有无法匹敌的灵敏度(通过前向角散射光FC500只能勉强区分0.5μm和0.9μm的微珠,0.5μm以下的微珠则完全无法区分;Gallios和Influx在散射光检测能力方面有所提高,可以区分0.3μm和0.5μm的微珠,但0.3μm以下的微珠还是无法区分;而Apogee A50-Micro可以轻松地将0.14μm的微珠和0.3μm的微珠分成两个群(Fig
610A 采用 CytoFLEX 流式细胞仪上的紫光侧向散射光,有利于进行亚微颗粒分析和计数
背景和目标基于 FCM 的纳米颗粒(SMP)检测需要特殊的散射光参数设置。该参数的设置和标准化可以用微球作为 QC 工具实现。目标:采用流式细胞仪 (FCMr) 对 SMP 进行分析和计数。● 采用微球对最有用的散射参数(FSC 或 SSC)进行测定● 采用先前的标准化设置(1、2)对其标准化效果进行测试● 对比蓝光和紫光 SSC 的散射灵敏度和分辨率● 确认采用质控微球检测散射分辨率得到的增益值,是否会使检测细胞源微颗粒(MP ,亦称为 EV)具有较高灵敏度检测出现灵敏度增益值。● 测试体积
板体外活化→荧光染色(FITC、PE、PerCP三色荧光)→上机操作→分析数据。 荧光染色 BDIS抗体 FITC PE PerCP 对照管 PAC-1+RGDS IgG1 CD61 试验管 PAC-1 CD62P CD61 三色流式细胞分析法可以同时检测血小板反应性及其活化进程,能直接、同时检测多种血小板表面标志,使用全血、样本量少,操作简便快捷,将血小板人工活化降至最低。 (1)血小板微粒的测定 血小板微粒(PMPs)是血小板被激活后从质膜脱落进入外周循环的细小微粒
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