為納米技術(shù)研究市場(chǎng)提供光學(xué)圖像處理的CytoViva公司將一種新型光譜圖像技術(shù)(HSI)引入到**納米顯微鏡系統(tǒng)中���。這種技術(shù)的結(jié)合將幫助科學(xué)家在納米醫(yī)學(xué)和納米材料研究取得重大進(jìn)展��。 在過去的幾年里�����,CytoViva的“納米顯微鏡系統(tǒng)"被很多****納米技術(shù)研究機(jī)構(gòu)采納����,包括世界研究醫(yī)院�����,約翰霍普金斯醫(yī)學(xué)院�、德州安德森癌癥中心、美國FDA����、NASA�,NIH等。這一技術(shù)受到廣泛好評(píng)��,并獲得兩項(xiàng)RD100大獎(jiǎng),一項(xiàng) Nano50 大獎(jiǎng)�。
CytoViva?納米熒光高光譜顯微成像系統(tǒng)(HSI),可以同時(shí)提供納米材料及生物樣品的光譜分析和圖像數(shù)據(jù)����。該系統(tǒng)在可見-近紅外光譜范圍內(nèi)(VNIR)進(jìn)行數(shù)據(jù)采集,提供定量及定性分析數(shù)據(jù)�����,對(duì)活體細(xì)胞和納米材料的熒光或非熒光成分適用��。
雙模式熒光顯微成像系統(tǒng):支持熒光標(biāo)記和非熒光標(biāo)記物質(zhì)同時(shí)觀察�;支持無機(jī)物質(zhì)如:liposome,環(huán)碳納米管��,及其它納米粒子觀察和組織切片��、細(xì)胞的熒光/非熒光成像�����;支持光譜分析等功能�。
CytoViva?是一種應(yīng)用在生物醫(yī)學(xué)和納米技術(shù)研究領(lǐng)域的緊湊,超高對(duì)比度����,超高分辨率��,實(shí)時(shí)光學(xué)顯微鏡����。該CytoViva?的光學(xué)照明系統(tǒng)是****的��,取代了標(biāo)準(zhǔn)的顯微鏡聚光器���,并提供優(yōu)化的光學(xué)分辨率和檢測(cè)����?����?茖W(xué)家們可以快速����,方便地觀察各種各樣的納米材料。觀察到在傳統(tǒng)光學(xué)成像技術(shù)無法觀測(cè)到的��,活細(xì)胞和**的細(xì)節(jié)�。通過將CytoViva雙模熒光系統(tǒng),研究人員還可以觀察到熒光標(biāo)記的納米顆粒���,與無標(biāo)記的**和活細(xì)胞的相互作用�����。這種獨(dú)特的技術(shù)可以無需計(jì)算機(jī)的特殊處理���,只需兩種不同的照明方式和**的軟件程序。
CytoViva?是一種**性的產(chǎn)品����,能夠創(chuàng)造新的熒光和高分辨率結(jié)合的光學(xué)顯微成像,達(dá)到****的水平��。這種獨(dú)特的系統(tǒng)使研究人員能夠實(shí)時(shí)的��,高分辨率的同時(shí)觀察兩個(gè)熒光和非熒光樣品的結(jié)構(gòu)���。擁有CytoViva?�����,研究人員現(xiàn)在就可以在自己的實(shí)驗(yàn)室�����,隨時(shí)動(dòng)態(tài)觀察亞100nm的納米材料和生物活體標(biāo)本的高分辨率成像�。
CytoViva?將您現(xiàn)有的研究顯微鏡的性能提升到一個(gè)新的水平。
實(shí)時(shí)觀察:
· 活細(xì)胞和納米材料的亞100納米分辨率
· 同時(shí)熒光和非熒光樣品結(jié)構(gòu)
納米高光譜顯微成像系統(tǒng):高光譜成像系統(tǒng)配合納米顯微成像系統(tǒng)���,可以廣泛應(yīng)用于量化細(xì)胞和組織中的納米材料����。該系統(tǒng)捕獲掃描范圍內(nèi)近紅外(400-1000nm)內(nèi)每個(gè)像素的光譜信號(hào)�;每一像素的完整光譜被CCD采集,光譜分辨率高達(dá)2nm�����,這些數(shù)據(jù)同時(shí)以光譜曲線和RGB圖像形式呈現(xiàn)����,每一個(gè)視野的詳細(xì)定量分析可以被執(zhí)行,**的分析軟件可以提供的掃描材料的詳細(xì)光譜信息���。適用于納米**輸送和納米毒理學(xué)領(lǐng)域����。 此高光譜分析方法既支持活細(xì)胞和納米材料的非熒光標(biāo)記,也支持熒光標(biāo)記����。
雖然這個(gè)系統(tǒng)是專門設(shè)計(jì)用于支持納米級(jí)的研究��,同時(shí)它也支持一個(gè)廣泛的�,如細(xì)胞生物學(xué)和傳染性**領(lǐng)域的生物醫(yī)學(xué)研究。
Dr. Carlos Lopez-Estrano : University of Memphis College of Medicine
Dr. John Elliott: NIST
納米熒光高光譜成像
下面的圖片是CytoViva?系統(tǒng)在納米生物研究領(lǐng)域有代表性的一個(gè)典型應(yīng)用���。此文章說明了CytoViva?系統(tǒng)對(duì)100nm的納米金顆粒��,和一個(gè)活上皮細(xì)胞結(jié)合能力的量化�。
技術(shù)參數(shù):
應(yīng)用領(lǐng)域:
納米材料��、納米醫(yī)藥�、納米**遞送、納米毒理學(xué)�����、細(xì)胞生物學(xué)�、病理學(xué)、病毒學(xué)、植物學(xué)......
英文介紹
The CytoViva® Microscope System
Specifically designed to support research in nanotechnology and infectious disease, CytoViva employs a patented (US patents No. 7,542,203, 7,564,623) darkfield-based optical illumination system. This structured illumination technology replaces the standard condenser on a research grade microscope. By improving the alignment and focus of darkfield or oblique angle illumination, the technology enhances signal-to-noise of nanoscale samples up to seven times over standard darkfield optics. This enables scientists to optically observe a wide range of nanoscale materials quickly and easily in solution, live cells, tissue and materials based matrices. In addition, non-fluorescent live cells and pathogens can be easily observed at a level of detail not possible with traditional optical imaging techniques such as phase contrast or differential interference contrast.
When using the CytoViva Dual Mode Fluorescence system, researchers can also observe the interactions between fluorescently labeled nano-particles or bacteria and live unlabeled cells. This unique capability can eliminate the need to create computer enhanced overlay images which require two different illumination methods and advanced software programs. Finally, when combined with CytoViva’s Hyperspectral Imaging capability this high signal-to-noise microscopy method enables researchers to spectrally characterize and map nanoscale samples in a wide range of environments.
用戶評(píng)價(jià):
J. Paul Robinson, PhD, Director of Purdue University's Cytometry Laboratory, Professor of Basic Medical Sciences and Biomedical Engineering, Purdue University comments...
""It's like not knowing you need glasses. You don't know what you can't see. Then someone hands you a pair-and the world is clear with amazing detail.""
John A. Smith, MD, PhD, MMM, Divisional Director, Department of Pathology, University of Alabama-Birmingham says it well ...
""Looking through CytoViva, you are face to face with living biology. You see into the world of cell biology
that you didn't know existed. You are visualizing the future of underlying biological processes as it merg
es with the present.""
Dr. Elaine Coleman, Associate Professor, Auburn University, Department of Anatomy, Physiology and Pharmacology comments...
""Its capabilities in cell culture research are astounding. I have purchased a unit for my future research because its capabilities are unique for observing live cell cultures.""
部分用戶:
National Institute for Occupational Health
US Food and Drug Administration
Finnish Institute for Occupational Health
National Institute of Health Sciences Japan
Melbourne Center for Nanofabrication
US Army Corp of Engineers
Lawrence Berkeley National Labs
IIT Madras
Rice University
Fraunhofer Institute
Adolph Merkle Institute
University of Sao Paulo
Health Canada
Stanford University
University of Bonn
Georgia Tech University
Duke University
University of Montreal
Wright Patterson AFB
MD Anderson Cancer Center
Center for Nanoscale Science and Engineering
文獻(xiàn):
有超過300篇用CytoViva?納米熒光高光譜顯微成像系統(tǒng)發(fā)表的第三方文獻(xiàn)�,這是*近發(fā)表的部分文獻(xiàn):
Hyperspectral imaging for cellular iron mapping in the in vitro model of Parkinson's disease
Eung Seok Oh, Chaejeong Heo, Ji Seon Kim, Minah Suh, Young Hee Lee, Jong-Min Kim
Journal of Biomedical Optics | Volume 19 | Issue 5 | Special Section on Nanobio-Based Optical Sensing and Imaging 2014
Optical hyperspectral investigation of the J-pole and Vee antenna families
Timothy D. James, Timothy J. Davis, and Ann Roberts
Optics Express, Vol. 22, Issue 2, pp. 1336-1341 (2014)
In Vitro Identification of Gold Nanorods through Hyperspectral Imaging
Bradley M. Stacy, Kristen K. Comfort, Donald A. Comfort, Saber M. Hussain
Plasmonics June 2013, Volume 8, Issue 2, pp 1235-1240
Hyperspectral enhanced dark field microscopy for imaging blood cells
Giulia Sacco Verebes, Michele Melchiorre2, Adianez Garcia-Leis, Carla Ferreri, Carla Marzetti,
Armida Torreggiani
Journal of Biophotonics Volume 6, Issue 11-12, pages 960–967, December 2013