![]() By January 2010, the company delivered the first version of its cloud-based platform, iPass Open Mobile. During Kaplan's tenure, the firm began to build a service delivery platform for its new enterprise mobility services. In 2008, the company appointed Evan Kaplan as CEO and President to replace Denman. Overall, total revenues grew to $192 million by the end of 2007. ![]() In the midst of these acquisitions, iPass recorded year-end revenue growth, despite declining revenues from the company's traditional dial-up business. Two years later, iPass acquired GoRemote Internet Communications, a former rival in the corporate remote access market. In pursuing this initiative, iPass acquired two companies in 2004: Safe3w, which developed patented dynamic device “fingerprinting” technology, and Mobile Automation, which specialized in mobile device management. In 2004, the firm launched a policy orchestration initiative to integrate patch management, assessment and remediation of remote and mobile computers into its connectivity platform. In July 2003, the firm successfully issued its IPO, raising over $100 million. Kenneth Denman succeeded Mansouri as President and CEO in 2001, later assuming the position of Chairman in 2003. Mansouri, who took the position of Chairman, President and CEO in 1999, serving until 2001. IPass was founded in January 1996 by Chris Moore, and was later replaced by Michael H. The company's stock was added to the NASDAQ on July 24, 2003. The firm was first incorporated in California in July 1996 and later reincorporated in Delaware in June 2000. Together, these constrain the area where Raman scattering can occur, which means the final stage, imaging, can detect the probe at the very precise point, which leads to a high spatial resolution.IPass Inc was an American multinational company headquartered in Redwood Shores, California, that provided internet software and services. For that to occur, the sample is then irradiated with two-color infrared laser pulses for detecting Raman scattering, ultraviolet light and a special donut-shaped beam of visible light. Next, the sample is placed within an optical apparatus used to correctly illuminate the sample and build an image of it. Firstly, the specific components of the sample to be imaged need to be labeled, or stained, with special chemicals called photoswitchable Raman probes, whose Raman scattering can be controlled by the different kinds of laser light employed by RESORT. There are several stages to RESORT imaging, and although it might seem complicated, the setup is less complicated than that of the techniques it's aiming to replace. While the difference may look subtle at first glance, the sharper image offered by RESORT can be of great benefit to researchers identifying and labeling components of cells, such as mitochondria. We successfully performed RESORT imaging of mitochondria in cells to validate the technique."Ī comparison of RESORT and a prior imaging technique known as stimulated Raman scattering (SRS). It is a laser-based technique that uses something known as Raman scattering, a special interaction between molecules and light which helps identify what's in a sample under the microscope. "RESORT stands for reversible saturable optical Raman transitions, and it combines the benefits of super-resolution fluorescence and vibrational imaging without inheriting the detriments of either. "We were motivated by the limitations of these kinds of imaging techniques to try and create something better, and with RESORT we are confident that we have achieved this," said Professor Yasuyuki Ozeki from the University of Tokyo's Research Center for Advanced Science and Technology. Two leading technologies are: super-resolution fluorescence imaging, which offers good spatial resolution, and vibrational imaging, which compromises spatial resolution but can use a broad range of colors to help label many different constituents in cells. ![]() The more we can see, the more we can understand, hence the pressure to improve those tools we use to explore the world around us, and inside us.Ĭontemporary microscopic imaging techniques go far beyond those that traditional microscopes can offer. For as long as humanity has been able to manipulate glass, we have used optical devices to peer at the microscopic world in ever increasing detail.
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