02351nam 2200445 450 99658116520331620231205170136.01-5044-8996-9(IEEE)9904594(CKB)25047742700041(NjHacI)9925047742700041(EXLCZ)992504774270004120231205d2022 uy 0engur|||||||||||txtrdacontentcrdamediacrrdacarrier"White Paper - Cybersecurity in Agile Cloud Computing - Cybersecurity Guidelines for Cloud Access" /David Tayouri [and three others]New York :IEEE,2022.©20221 online resource (36 pages)Organizations demand immediate, uninterrupted access for their users, no matter where they are located. Digital business transformation efforts, adopting Software as a Service (SaaS), working from home (especially following the COVID-19 pandemic), and emerging edge computing platforms have changed how enterprises work. Digital business transformation requires anywhere, anytime access to applications and services--many of which are located in the cloud. The enterprise perimeter can now be everywhere--a dynamically created, policy-based secure access service edge. Enterprises want to protect their assets from unauthorized entities. Still, they also want to keep business continuity by allowing trusted devices and users to access applications hosted on-premises or in the cloud. To achieve this, one of the most critical security layers is secure remote access. This paper presents the cloud security guidelines and best practices, emphasizing secure remote access.Cloud computingComputer securityComputer networksSecurity measuresCloud computing.Computer security.Computer networksSecurity measures.004.6782Tayouri David1592775Hassidim SnirSmirnov AlexShabtai AsafNjHacINjHaclDOCUMENT996581165203316"White Paper - Cybersecurity in Agile Cloud Computing - Cybersecurity Guidelines for Cloud Access"3912142UNISA05524nam 2200577z- 450 991022734940332120210212(CKB)4100000000883839(oapen)https://directory.doabooks.org/handle/20.500.12854/57439(oapen)doab57439(EXLCZ)99410000000088383920202102d2017 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierQuantitative Biology: Dynamics of Living SystemsFrontiers Media SA20171 online resource (136 p.)Frontiers Research Topics2-88945-213-1 With the emergence of Systems Biology, there is a greater realization that the whole behavior of a living system may not be simply described as the sum of its elements. To represent a living system using mathematical principles, practical quantities with units are required. Quantities are not only the bridge between mathematical description and biological observations; they often stand as essential elements similar to genome information in genetics. This important realization has greatly rejuvenated research in the area of Quantitative Biology. Because of the increased need for precise quantification, a new era of technological development has opened. For example, spatio-temporal high-resolution imaging enables us to track single molecule behavior in vivo. Clever artificial control of experimental conditions and molecular structures has expanded the variety of quantities that can be directly measured. In addition, improved computational power and novel algorithms for analyzing theoretical models have made it possible to investigate complex biological phenomena. This research topic is organized on two aspects of technological advances which are the backbone of Quantitative Biology: (i) visualization of biomolecules, their dynamics and function, and (ii) generic technologies of model optimization and numeric integration. We have also included articles highlighting the need for new quantitative approaches to solve some of the long-standing cell biology questions. In the first section on visualizing biomolecules, four cutting-edge techniques are presented. Ichimura et al. provide a review of quantum dots including their basic characteristics and their applications (for example, single particle tracking). Horisawa discusses a quick and stable labeling technique using click chemistry with distinct advantages compared to fluorescent protein tags. The relatively small physical size, stability of covalent bond and simple metabolic labeling procedures in living cells provides this type of technology a potential to allow long-term imaging with least interference to protein function. Obien et al. review strategies to control microelectrodes for detecting neuronal activity and discuss techniques for higher resolution and quality of recordings using monolithic integration with on-chip circuitry. Finally, the original research article by Amariei et al. describes the oscillatory behavior of metabolites in bacteria. They describe a new method to visualize the periodic dynamics of metabolites in large scale cultures populations. These four articles contribute to the development of quantitative methods visualizing diverse targets: proteins, electrical signals and metabolites. In the second section of the topic, we have included articles on the development of computational tools to fully harness the potential of quantitative measurements through either calculation based on specific model or validation of the model itself. Kimura et al. introduce optimization procedures to search for parameters in a quantitative model that can reproduce experimental data. They present four examples: transcriptional regulation, bacterial chemotaxis, morphogenesis of tissues and organs, and cell cycle regulation. The original research article by Sumiyoshi et al. presents a general methodology to accelerate stochastic simulation efforts. They introduce a method to achieve 130 times faster computation of stochastic models by applying GPGPU. The strength of such accelerated numerical calculation are sometimes underestimated in biology; faster simulation enables multiple runs and in turn improved accuracy of numerical calculation which may change the final conclusion of modeling study. This also highlights the need to carefully assess simulation results and estimations using computational tools.Quantitative BiologyNeurosciencesbicssccell divisiondata visualizationfluorescence chemistryGPGPUimagingmodel optimizationmolecular crowdingnumerical integrationquantum dotNeurosciencesNoriko Hiroiauth1296690Douglas B. MurrayauthViji M. DraviamauthChun-Biu LiauthHiroaki TakagiauthZiya KalayauthTetsuya J. KobayashiauthAkira FunahashiauthAkatsuki KimuraauthRinshi S. KasaiauthNaoki A. IrieauthJason Edward ShoemakerauthBOOK9910227349403321Quantitative Biology: Dynamics of Living Systems3024226UNINA