02060nam 2200481 450 00001277720050718115500.03-540-19233-620030502d1988----km-y0itay0103----baengDETwo-parameter martingales and their quadratic variationPeter ImkellerBerlin [etc.]Springerc1988IV, 177 p.25 cm.Lecture notes in mathematics13082001Lecture notes in mathematicsProbabilitàTeoriaProcesso stocastico519.287(21. ed.)Probabilità e matematica applicata. Speranza matematica e previsione60G07Stochastic processes. General theory of processes60G44Stochastic processes. Martingales with continuous parameter60E15Probability theory and stochastic processes. Distribution theory. Inequalities; stochastic orderings60G42Stochastic processes. Martingales with discrete parameter60G48Stochastic processes. Generalizations of martingales60G55Stochastic processes. Point processes60G60Stochastic processes. Random fields60H05Probability theory and stochastic processes. Stochastic analysis. Stochastic integralsImkeller,Peter57607ITUniversità della Basilicata - B.I.A.RICAunimarc000012777Two-parameter martingales and their quadratic variation78540UNIBASMONSCISCIENZEEXT0030120030502BAS011822EXT0030120030512BAS01084020050601BAS011755batch0120050718BAS01105120050718BAS01111020050718BAS01114020050718BAS011155BAS01BAS01BOOKBASA2Polo Tecnico-ScientificoGENCollezione generaleMAT58799S587992003050251Riservati03947oam 2200541z 450 991013722210332120240827055825.0(CKB)3710000000520097(SSID)ssj0001666196(PQKBManifestationID)16455617(PQKBTitleCode)TC0001666196(PQKBWorkID)15000834(PQKB)10835630(WaSeSS)IndRDA00056026(oapen)https://directory.doabooks.org/handle/20.500.12854/42024(oapen)doab42024(EXLCZ)99371000000052009720160829d2014 fy 0engurmn#---|||||txtrdacontentcrdamediacrrdacarrierBeyond the borders the gates and fences of neuroimmune interaction /topic editors Javier Velázquez-Moctezuma, Emilio Domínguez-Salazar and Beatriz Gómez-GonzálezFrontiers Media SA2014Lausanne, Switzerland :Frontiers Media SA,2014.©20141 online resource (119 pages) charts; digital, PDF file(s)Frontiers Research TopicsBibliographic Level Mode of Issuance: Monograph2-88919-274-1 Includes bibliographical references.Beyond the borders: the gates and fences of neuroimmune interaction --Section 1 --Section 2 --Section 3 --Section 4.Neuroimmunology is a rapidly growing emerging field at which two old sciences have converged to integrate two different types of responses into a single coherent response involving the coordinated action of both systems, neural and immune. During long time it was thought that both systems worked separately and in divergent pathways. The brain was considered an immunoprivileged site and the immune organs were deemed as independent of any neural influence and also of nervous innervation. Time has gone and has proven that the borders between both systems were merely artificial. Since the beginning of Neuroimmunology in the 1980s much work has been done to elucidate the gates and fences in neuro-immune interactions. Brain was shown to be under the continuous surveillance of the immune system, even under basal physiological conditions in the absence of any pathology. Likely, it was found a profuse nervous innervation of lymphoid organs and even of single immune cells. Gates for direct neural immune communication were found both centrally and peripherally. Centrally, the gates, but also the fences, were situated at the brain barriers, the blood-brain barrier and the blood-cerebrospinal fluid barrier, and at the circunventricular organs. Peripherally, the fences constituted the apparent diverse nature of molecules involved in neural and immune signaling; however, time proved that both system were capable of producing the same signaling molecules and also systematically responded to the molecules released by the other system. Therefore, the gates were open for direct neural-immune communication at the peripheral level. This Research Topic aims to include original reports, reviews and technical reports regarding the description of the gates and fences in neural immune interactions. We intend to provide an extensive view of the mechanisms governing central and peripheral neural-immune interactions, and the role of the borders, the blood-neural barriers, in the regulation of the neural-immune communication.NeurosciencesNeuroimmunologyNeurosciences.Neuroimmunology.Javier Velazquez-Moctezumaauth1765560Velázquez-Moctezuma JavierGómez-González BeatrizDomínguez-Salazar EmilioPQKBUkMaJRUBOOK9910137222103321Beyond the borders4207355UNINA06166nam 2201189z- 450 991055731460332120220111(CKB)5400000000042709(oapen)https://directory.doabooks.org/handle/20.500.12854/77117(oapen)doab77117(EXLCZ)99540000000004270920202201d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierNumerical Simulation in Biomechanics and Biomedical EngineeringBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (300 p.)3-0365-2211-5 3-0365-2212-3 In the first contribution, Morbiducci and co-workers discuss the theoretical and methodological bases supporting the Lagrangian- and Euler-based methods, highlighting their application to cardiovascular flows. The second contribution, by the Ansón and van Lenthe groups, proposes an automated virtual bench test for evaluating the stability of custom shoulder implants without the necessity of mechanical testing. Urdeitx and Doweidar, in the third paper, also adopt the finite element method for developing a computational model aim to study cardiac cell behavior under mechano-electric stimulation. In the fourth contribution, Ayensa-Jiménez et al. develop a methodology to approximate the multidimensional probability density function of the parametric analysis obtained developing a mathematical model of the cancer evolution. The fifth paper is oriented to the topological data analysis; the group of Cueto and Chinesta designs a predictive model capable of estimating the state of drivers using the data collected from motion sensors. In the sixth contribution, the Ohayon and Finet group uses wall shear stress-derived descriptors to study the role of recirculation in the arterial restenosis due to different malapposed and overlapping stent conditions. In the seventh contribution, the research group of Antón demonstrates that the simulation time can be reduced for cardiovascular numerical analysis considering an adequate geometry-reduction strategy applicable to truncated patient specific artery. In the eighth paper, Grasa and Calvo present a numerical model based on the finite element method for simulating extraocular muscle dynamics. The ninth paper, authored by Kahla et al., presents a mathematical mechano-pharmaco-biological model for bone remodeling. Martínez, Peña, and co-workers propose in the tenth paper a methodology to calibrate the dissection properties of aorta layer, with the aim of providing useful information for reliable numerical tools. In the eleventh contribution, Martínez-Bocanegra et al. present the structural behavior of a foot model using a detailed finite element model. The twelfth contribution is centered on the methodology to perform a finite, element-based, numerical model of a hydroxyapatite 3D printed bone scaffold. In the thirteenth paper, Talygin and Gorodkov present analytical expressions describing swirling jets for cardiovascular applications. In the fourteenth contribution, Schenkel and Halliday propose a novel non-Newtonian particle transport model for red blood cells. Finally, Zurita et al. propose a parametric numerical tool for analyzing a silicone customized 3D printable trachea-bronchial prosthesis.Technology: general issuesbicssc3D model3D printing3D scaffoldadditive manufacturingaortic dissectionbiomechanicsblood flow modellingbone disordersbone physiologybone tissue engineeringcardiac cellcardiac muscle tissuecardiomyocytecell dynamicscohesive zone modelcomputational cost analysiscomputational fluid dynamicscopulascustomized prosthesisdelamination testsdesign of experimentsdivergenceelectrical stimulationexplicit FEMfinite element analysisfinite element methodfinite element modellingfixed pointsfoot and ankle modelfoot finite element methodglioblastoma multiformehaemorheologyhemodynamicshepatic arteryimplant designimplicit FEMin-silicoliver cancermachine learningmalappositionmanifoldsmathematical modelmathematical modellingmicromotionMorse theoryNavier-Stokes equationsnumerical fluid mechanicsoverlapparametric modelparticle transportpatient specificpersonalized medicineplantar pressureporcine aortapotential swirling flowradioembolizationreverse shoulder arthroplastyseparated meshshared nodesshoulder implant stabilityskeletal musclesmart drivingstenosisstentthrombosistime seriestopological data analysistornado-like jetstracheobronchial stentunsteady swirling flowvascular mechanicsTechnology: general issuesMalvè Mauroedt1289210Malvè MauroothBOOK9910557314603321Numerical Simulation in Biomechanics and Biomedical Engineering3021089UNINA