European Conferences on Biomedical Optics (ECBO)

European Conferences on Biomedical Optics (ECBO)

25 - 29 June 2017
Messe Munich, Munich, Germany

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Sponsored by OSA and SPIE, the European Conferences on Biomedical Optics (ECBO) bring together scientists, engineers, and clinicians who work with optics and photonics to solve problems in medicine and biomedicine. Presentations will cover basic science, novel technology and applications in the areas of advanced microscopy, clinical and biomedical spectroscopy, diffuse optical imaging, molecular imaging, optical coherence tomography and other coherence techniques, therapeutic laser applications, laser-tissue interactions, opto-acoustic methods, and other novel biophotonics techniques.

ECBO will be held as part of the World of Photonics Congress.  With its conferences, subconferences, short courses, poster sessions and symposia, the World of Photonics Congress covers all reseach disciplines and application facets relevant to optical technologies.


Clinical and Preclinical Optical Diagnostics
Diffuse Optical Spectroscopy and Imaging
Novel Biophotonics Techniques and Applications
Advances in Microscopic Imaging
Opto-Acoustic Methods and Applications
Optical Coherence Imaging Techniques and Imaging in Scattering Media
Medical Laser Applications and Laser-Tissue Interactions
Head and Neck Optical Diagnostics and Intervention (held in conjunction with ECBO)

Clinical and Preclinical Optical Diagnostics

Spectroscopic and imaging methods have become valuable tools for both pre-clinical and clinical applications, ranging from in vivo tissue monitoring to the investigation of excised samples on the molecular scale. In clinical diagnostics, optical spectroscopy and imaging provides detailed structural and functional information on organs, tissues and body liquids. Basic preclinical biomedical applications include the detailed investigation of tissues and cells down to the level of single molecules, helping to understand the principles of cellular and sub-cellular processes that contribute to the early transformation of normal to diseased tissue, such as when malignant tumours are developed.

This conference provides an interdisciplinary platform to promote interaction between physicians, physicists, engineers, biologists, chemists and related researchers, in order to strengthen an integrated and holistic understanding of normal tissue development and the genesis of diseases, with the ultimate goal of using this understanding to develop and translate new, more efficient diagnostic and treatment modalities.

Contributed papers are solicited on, but not limited to, all areas of development and pre-clinical or clinical application of optical spectroscopy and imaging, including steady-state and time-resolved fluorescence, autofluorescence, linear and nonlinear microscopies, linear and nonlinear Raman, NIR, polarization, laser speckle, back-reflectance, light scattering spectroscopy, and combined approaches (multimodal imaging):
A. Biomedical and clinical applications
  • in vivo diagnostics and physiological monitoring (structural and functional spectral imaging of cells, tissues, organs), including endoscopic, noninvasive and minimally invasive methods
  • tissue pathology and tissue characterization
  • spectral biomarker analysis
  • spectroscopic micro- and nanosensors
  • biochip technology for point-of-care diagnostics
  • guidance and monitoring of therapies
  • diagnostics and tissue engineering.
B. Investigation of cellular and sub-cellular processes
  • analysis of cell dynamics by single-molecule techniques
  • high spatial resolution microscopy
  • structural analysis of cells and tissues on the nano-to-microscale
  • cellular metabolic sensing and imaging
  • biomarker discovery for spectroscopic techniques.

Diffuse Optical Spectroscopy and Imaging

The study of diffuse light spectroscopy and imaging in tissue continues to provide new insight into the structural and functional properties of tissues that are not easily accessed by alternative methods. The research and development of systems that exploit this approach has led to clinical prototype systems that are used in basic studies and medical research. Scientific applications range from the study of cerebral physiology to cancer patho-physiology in both animals and humans. Medical applications being explored encompass detection and diagnosis of breast cancer, brain cancer, cognitive neuroscience, stroke, hemorrhages, brain and muscular oxygenation, peripheral vascular diseases and joint diseases as well as establishing novel methods in drug discovery and tracking. Integration of diffuse light spectroscopy and imaging into existing clinical instrumentation is a key area of development, and combining diffuse light with new contrast agents or other imaging modalities are also emerging as major growth areas.

Further improvement in these and other application areas relies on continued advancement in the theory of radiation transport through random media, in data analysis and image reconstruction algorithms, and in instrumentation design.

This meeting provides a key interdisciplinary forum for engineers, physicists, mathematicians, biomedical scientists and physicians to report on recent results, improvements, and new approaches and applications for using diffusing light to characterize the structural and functional properties of tissue.

Contributed papers are solicited concerning, but not limited to, the following areas:
  • Diffuse optical tomography and spectroscopy
  • Diffuse fluorescence and bioluminescence imaging
  • Diffuse correlation spectroscopy
  • Novel molecular contrast agents
  • Hybrid-modality imaging with diffuse light
  • Modeling of light propagation
  • Tissue optical properties
  • Image reconstruction algorithms
  • Instrumentation, spectroscopy and imaging systems
  • Clinical and preclinical applications of diffuse optics
  • Muscle physiology studies
  • Breast cancer imaging and spectroscopy
  • Brain monitoring and imaging of functional activation, oxygenation, stroke, hemorrhage, etc.

Novel Biophotonics Techniques and Applications

Aside from the well-recognized avenues of biomedical optics for diagnostics, therapeutics and analytics/microscopy, a number of novel and highly promising approaches are under development. These new techniques often rely on the confluence of two or more diverse fields, drawing on their complementarity in order to overcome the inherent complexity and heterogeneity of biological tissues. Examples include mid-infrared spectroscopy, laser induced breakdown spectroscopy, holography, phase and polarization imaging, photodiagnostics in monitoring and guiding therapies in real time (“theranostics”), and the use of MRI to constrain optical tomographic reconstructions. These approaches are driven by task-specific (functional or cost) requirements of a particular application. Moreover, a number of new ideas are being investigated based on new methodologies, physical basis, instrument development, integration of techniques and data analysis. This conference will present a highly interdisciplinary discussion forum of interest to instrument designers, sensor builders, basic and applied clinical researchers, and other scientists interested in exploring novel directions in biophotonics. 

Topics for contributions are thus broadly open and include:

  • photothermal imaging and diagnostics
  • speckle-based techniques
  • polarized light diagnostics
  • holography and micro-holography
  • laser induced breakdown spectroscopy
  • radiomics
  • theranostics
  • lab-on-a-chip approaches
  • micro-fluidics
  • quantitative low level laser therapy
  • optical waveguides
  • nano-probes and nano-biophotonics
  • lensless imaging
  • MRI/optical image fusion
  • novel technologies and studies in endoscopy
  • ultrasound/optical image fusion
  • new approaches for ophthalmology
  • new approaches for photon discrimination in turbid media
  • hybrid approaches in photomedicine
  • other new/emerging biophotonic techniques

Advances in Microscopic Imaging

This conference will explore the rapidly devel­oping field of multidimensional microscopy, including confocal microscopy, nonlinear optical microscopies, super-resolution microscopies, light sheet-based microscopy and other novel imaging modalities. Consideration will be given to the characteristics of the overall system de­sign, as well as to topics of contrast, image formation, image recording, deconvolution, and digital methods of produc­ing and displaying the resulting reconstruction. Recent innovations in multi-dimensional micros­copy have a serious impact on the biological and medical fields. We hope that the broad range of relevant topics presented at this conference will encourage the interaction among instrumentation engineers, computer image analysts, and researchers in the various fields of biomedical and life science application.

Papers are invited on all areas of development and application of confocal, nonlinear optical, and novel optical microscopies including, but not limited to, the following and related areas:
  • high resolution optical imaging on the nanometer scale (e.g. PALM, STORM, STED)
  • fast imaging of large and complex biological specimens (e.g. SPIM, DSLM)
  • multiphoton microscopy, SHG, THG, CARS, SRS, FWM microscopies using exogenous and/or endogenous contrast
  • adaptive optics, spatial and temporal control of the excitation
  • endoscopic microscopy
  • single molecule microscopy and microanalysis
  • phase microscopy, holographic based microscopy, absorption microscopy, polarization microscopy
  • multi-modal spectroscopic analysis in microscopy
  • novel image contrast enhancement approaches such as SER and other near field surface effects
  • FRET-FLIM modalities, Fluorescence Correlation Spectroscopy
  • biomedical instrumentation
  • micro-optics and MEMS based optical systems for the biomedical diagnosis
  • fast image acquisition with time-resolving image acquisition systems
  • applications to cell biology, developmental biology, animal models
  • clinical applications of optical microscopy
  • macroscopic imaging obtained with microscopy, when using high spatial dynamic range microscopy
  • advanced methods in neurophotonics.

Opto-Acoustic Methods and Applications

In the last decade optoacoustic (photoacoustic) imaging has grown significantly to a powerful optical imaging platform suitable for basic research, clinical translation, and drug discovery. Advances in the system design, laser and ultrasound detection technology in conjugation with the ability to visualize a large range of anatomical, functional and molecular bio-markers have led to new and exciting ways of visualizing structure and function in biological tissue. 

One of the promising aspects of the optoacoustic methodology is its versatility, manifested in the numerous distinct imaging concepts employed in it: multispectral imaging, nonlinear imaging, real-time imaging, tomography, microscopy, endoscopy, etc. Label-free imaging of functional parameters of vasculature including hemoglobin oxygenation and oxygen metabolism can be combined with simultaneous detection of exogenous molecular agents to provide more complete views of pathologies at appropriate scales from optical diffraction-limited microscopy to depths of several centimeters. 

Additionally, the ability to detect nanoparticles of interest by means of their optical absorption enables unique in vivo visualization. This emerging field of the imaging sciences integrates many scientific disciplines from physics and engineering to chemistry and biotechnology. It is the aim of this conference to bring together those disciplines which make up the optoacoustic field with particular emphasis on development and adaption of optoacoustic technology to enable novel biological and clinical applications. All areas in optoacoustic sensing and imaging are welcomed, from hardware and algorithmic developments, to novel concept, applications and contrast generation mechanisms, including photo-absorbing agents and nanoparticles. 

Areas of interest consider, but are not limited to, progress in the following topics:
  • imaging and tomography
  • optoacoustic microscopy
  • multi-spectral approaches
  • theory and image reconstruction algorithms
  • small animal imaging
  • clinical imaging
  • genetic reporters and cell-labeling for optoacoustic imaging
  • novel agents and nanoparticles
  • novel detection technologies
  • novel illumination technologies
  • nonlinear optoacoustics
  • doppler phenomena
  • multi-modality imaging.

Optical Coherence Imaging Techniques and Imaging in Scattering Media

This conference is a continuation of “Optical Coherence Tomography and Coherence Techniques” and seeks to broaden the scope to cover the general area of imaging in biological scattering media based on coherent light and its interactions with biological tissues. The conference provides an interdisciplinary forum for topics in research and development on a physical and theoretical basis of coherent imaging including techniques like optical coherence tomography/microscopy, adaptive optics ophthalmoscopy, nonlinear coherence imaging, photothermal and magnetomotive imaging and imaging with advanced wavefront control. In addition, this conference will focus on the development of new light sources, new probes, new detection schemes and new signal processing algorithms for coherent imaging. Applications of coherent optical techniques for morphological as well as functional assessment in different living tissues and phantoms in various medical fields are also covered. 

Contributed papers are solicited concerning, but not limited to, the following areas:
  • optical coherence tomography (OCT) - technology, systems and applications
  • imaging using advanced spatio-temporal light modulation
  • imaging in turbid media
  • holographic imaging
  • coherent imaging system, theory and signal processing
  • contrast enhancement techniques for coherence imaging
  • novel light sources and MEMS probes for coherence imaging
  • optical coherent techniques for tissue spectroscopy and imaging
  • coherent light microscopy
  • speckle analysis and methods for speckle reduction
  • adaptive coherent optical systems
  • multi-modal optical coherence imaging platforms.

Medical Laser Applications and Laser-Tissue Interactions

Medical laser application is a broad area for research and development with the vision of improving clinical therapeutic procedures or to extend into new fields for lasers in medical use. Novel biomedical laser applications are emerging due to the advent of new types of lasers that widen the possible spectrum of laser-tissue interactions to improve the target-oriented precise application of laser radiation in clinical practice. Laser light applications include the whole range of non-thermal to thermal reactions up to ionization effects either on the macro-scale, e.g. soft tissue smoothing without ablation, or on the micro scale, e.g. selective retina therapy, to the nano-scale for surgery within cells, as well as short-pulsed laser applications to treat soft and hard tissue in patients. In addition to that new laser light application techniques as well as innovative medical keyhole techniques such as laser assisted NOTES (Natural Orifice Transluminal Endoscopic Surgery) are under investigation.

Highly sophisticated targeting strategies including endogenous or applied chromophores as well as conjugation of chromophores or nanoparticles with antibodies pave the way for new treatment modalities. Furthermore combination therapies such as the synergetic use of photodynamic therapy and immunomodulatory or antiseptics are encouraging new fields for research and clinical studies.
Improved understanding of biological reactions triggered by laser radiation interacting with natural absorbing sites, targeting molecules, photosensitizers, or nanoparticles will lead to progress in the creation of minimally-invasive clinical laser light applications or assist in elucidating particular immunological responses from the tissue.

Theoretical considerations and modeling of laser light distribution in tissue with subsequent energy transfer and tissue interactions constitute a solid basis for therapy planning in patients, particular if combined by improved light delivery and monitoring techniques. 

This conference will provide an interdisciplinary forum for scientists, engineers, technicians, and medical doctors using laser assisted treatment modalities to discuss the progress in all these topics. The forum joins presentations from in-vitro investigations up to clinical studies of new laser light irradiance in the range of 10(-3) – 10(18) Wcm(-2) to lead to actual clinical and medical questions where laser assisted techniques can play an important role in future.  Contributed papers are solicited concerning, but not limited to, the following topics:
  • photo-biological and photo-chemical reactions
  • photo-thermal and photo-mechanical tissue reactions
  • modelling of laser-tissue interactions
  • cellular micro- and nano-effects of laser radiation
  • nanoparticlaes for targeted phototherapies
  • laser-induced microdissection and catapulting of cells
  • tissue ablation and cutting with short and ultra-short laser pulses
  • hard tissue ablation, benign tissue destruction
  • photodynamic therapy (PDT) of tumors, neoplasia, and other pathologic conditions
  • antimicrobial PDT, PDT mediated immunology
  • cellular mechanisms of low power laser therapy
  • minimally invasive laser surgery
  • laser applications in NOTES
  • progress in therapeutic laser applications
  • in-vitro, ex-vivo, preclinical and clinical studies
  • experiences in clinical laser application .

Head and Neck Optical Diagnostics and Intervention (Held in Conjunction with ECBO)

The Head & Neck Optical Diagnostic Society (HNODS) was founded in 2008 in order to improve the early diagnosis and treatment of patients suffering from head & neck malignancies by promoting and encouraging the study and practice of optical diagnostics techniques, by facilitating communications between clinicians, scientists, physicists, engineers, technicians, radiologists and pathologists (particularly those with interest in the pathology of the head and neck) and by building close relations with laser, optical and surgical associations, societies, research groups, industry and patient‘s organizations.  We are anticipating to have some highly acclaimed experts in the field of head & neck optical diagnostics giving invited lectures, and are encouraging the submission of papers (free lectures and posters) of both young and experienced clinicians and researchers.

The methods that should have been applied in contributing papers include (but are not limited to):
  • Fluorescence Imaging (intensity and lifetime)
  • Spectroscopic methods
  • Optical Coherence Tomography / Microscopy
  • Photo-acoustic imaging
  • Probe-based Confocal Laser Endomicroscopy
  • Photodynamic Therapy
  • Photochemical Internalization.
Chairs

Rainer Leitgeb, Medical Univ. Vienna, Austria, Chair
Brett Bouma, Massachusetts General Hospital, USA, Program Chair
Paola Taroni, Politecnico di Milano, Italy, Program Chair

Clinical and Preclinical Optical Diagnostics Conference
J. Quincy Brown, Tulane Univ., USA, Chair
Ton Van Leeuwen, Univ Amsterdam Academisch Medisch CtrNetherlands, Chair
Caroline Boudoux, École Polytechnique MontréalCanada
Daniel Cote, Universite LavalCanada
Kishan Dholakia, Univ. of St AndrewsUK
Daniel Elson, Imperial College LondonUK
Sylvain Gioux, Universite de StrasbourgFrance
Jonathan Liu, Univ. of Washington, USA
Quan Liu, Nanyang Technological Univ.Singapore
Narasimhan Rajaram, Univ. of ArkansasUSA
Lise Randeberg, Norges Teknisk Naturvitenskapelige UnivNorway
Daniel Razansky, Technical Univ. of MunichGermany
Darren Roblyer, Boston Univ.USA
Göran Salerud, Linkopings UniversitetSweden
Janis Spigulis, Univ. of LatviaLatvia
Henricus Sterenborg, NKI / AMCNetherlands
James Tunnell, Univ. of Texas at AustinUSA
Siavash Yazdanfar, Corning Research & Development Corp., USA
Diffuse Optical Spectroscopy and Imaging Conference
Hamid Dehghani, Univ. of BirminghamUKChair
Heidrun Wabnitz, Physikalisch-Technische BundesanstaltGermanyChair
Regine Choe, Univ. of Rochester, USA
Davide Contini, Politecnico di Milano, Italy
Jean-Marc Dinten, CEA Grenoble, France
Turgut Durduran, ICFO -The Institute of Photonic Sciences, Spain
Adam Eggebrecht, Washington Univ. in St Louis, USA
Dirk Grosenick, Physikalisch-Technische Bundesanstalt, Germany
Adam Liebert, Nalecz Inst. Biocybernetics Biomed. Eng, Poland
Eiji Okada, Keio Univ., Japan
Juliette Selb, Harvard Medical School, USA
Novel Biophotonics Techniques and Applications Conference
Arjen Amelink, Erasmus MCNetherlandsChair
Alex Vitkin, Ontario Cancer Inst., CanadaChair
Vanderlei Salvador Bagnato, Univ. de São Paulo, Brazil
Daniel Cote, Ctr. de Recherche de l'Univ. Laval Robert-Giffard, Canada
Stanislav Y. Emelianov, The Univ. of Texas at Austin, USA
Dirk Faber, Academisch Medisch Ctr., The Netherlands
Venkataramanan Krishnaswamy, Dartmouth College, USA
Igor Meglinski, Univ. of Oulu, Finland
Seemantini K. Nadkarni, Harvard Medical School, USA
Günther Paltauf, Karl-Franzens-Univ. Graz, Austria
Gijs van Soest, Erasmus MC, Netherlands
Advances in Microscopic Imaging Conference
Emmanuel Beaurepaire, Centre National Recherche Scientifique, FranceChair
Francesco Pavone, European Lab for Non-Linear Spectroscopy, Italy, Chair
Peter So, Massachusetts Inst. of TechnologyUSAChair
Adela Ben-Yakar, The Univ. of Texas at Austin, USA
Paul J. Campagnola, Univ. of Wisconsin-Madison, USA
Daniel Côté, Ctr. de Recherche de l'Univ. Laval Robert-Giffard, Canada
Vincent Daria, Australian National University, Australia
Kishan Dholakia, Univ. of St. Andrews, UK
Andrew Dunn, The Univ. of Texas at Austin, USA
Turgut Durduran, Inst. of Photonic Sciences, Spain
Paul M French, Imperial College London, UK
Irene Georgakoudi, Tufts Univ., USA
Michael Hausser, UCL, UK
Rainer Heintzmann, Institut für Photonische Technologien e.V., Germany
Elizabeth Hillman, Columbia University, USA
Jan Huisken, Max-Planck-Institut für molekulare Zellbiologie und Genetik, Germany
Thomas Knopfel, Imperial College London, UK
Suliana Manley, Ecole Polytechnique Fédérale de Lausanne, Switzerland
Jerome Mertz, Boston Univ., USA
Nozomi Nishimura, Cornell Univ., USA
Shy Shoham, Technion-Israel Institute of Technology, Israel
Vinod Subramaniam, Univ. Twente, Netherlands
Ivo Vanzetta, Institut de Neurosciences de la Timone, France
Opto-Acoustic Methods and Applications Conference
Vasilis Ntziachristos, Technische Universität Munchen, GermanyChair
Roger Zemp, Univ. of AlbertaCanadaChair
Emmanuel Bossy, Ecole Supérieure de Physique et de Chimie Industrielles, France
Stanislav Emelianov, Univ. of Texas at Austin, USA
Jan Grimm, Memorial Sloan-Kettering Cancer Ctr., USA
Fabian Kiessling, University Aachen (RWTH), Germany
Michael Kolios, Ryerson University, Canada
Srirang Manohar, University of Twente, The Netherlands
Matthew O'Donnell, Univ. of Washington, USA
Alexander A. Oraevsky, TomoWave Labs., Inc., USA
Guenther Paltauf, Karl-Franzens-Univ. Graz, Austria
Amir Rosenthal, Helmholtz Zentrum München GmbH, Germany
Lihong Wang, Washington University in St. Louis, USA
Valdimir Zharov, UAMS, USA
 
Optical Coherence Imaging Techniques and Imaging in Scattering Media Conference
Maciej Wojtkowski, Polish Academy of Sciences, Poland, Chair
Stephen A. Boppart, Univ. of Illinois at Urbana-Champaign, USA, Chair
Wang-Yuhl Oh, KAIST, Korea, Chair
Andy Yun, Massachusetts General Hospital, USA
Peter E Andersen, Technical Univ. of Denmark, Denmark
Silvain Gigan, Inst. Langevin, France
Adrian Podoleanu, Kent Univ., UK
Michael Pircher, Medizinische Univ. Wien, Austria
Ivo Velekoop, Univ. Twente, Netherlands
James G. Fujimoto, MIT, USA
Robert A. Huber, Universitat Zu Lubeck, Germany
David D. Sampson, The Univ. of Western Australia, Australia
Wonshik Choi, Korea
Valentin Gelikonov, Inst. of Applied Physics, Russian Federation
Yoshiaki Yasuno, Univ. of Tsukuba, Japan
Johannes de Boer, Vrije Universiteit, Netherlands
Alfredo Dubra, Stanford Univ., USA
Michel Choma, Yale Univ., USA
Ben Vakoc, MGH, USA
Medical Laser Applications and Laser-Tissue Interactions Conference
Lothar Lilge, Univ. Health NetworkCanada, Chair
Ronald Sroka, Ludwig-Maximillians-Universitat Munchen, GermanyChair
Christian BetzKlinikum der Universität MünchenGermany
Ralf BrinkmannUniv. of LuebeckGermany
Santiago Camacho-LopezCICESEMexico
Matthias Domke, Munich Univ. of Applied Sciences, Germany
Martin Frenz, Universitat Bern, Switzerland
Mikhail KirillinInst. of Applied Physics RASRussia
Igor MeglinskiOulun YliopistoFinland
Serge Mordon, INSERM, France
Carsten PhilippElisabeth Klinik, Germany
Angelika RueckUniv. of UlmGermany
David SampsonUniv. of Western AustraliaAustralia
Herbert SteppLudwig-Maximilians-Universität Munchen, Germany
Valeri Tuchin, Saratov State Univ., Russia
Alfred VogelUniv. of LuebeckGermany
Georges WagnieresEcole Polytechnique Federale de LausanneSwitzerland
Head and Neck Optical Diagnostics and Intervention Conference
Max Witjes, Univ. Medical Center Groningen , NetherlandsChair
Christian BetzKlinikum der Universität MünchenGermany
Colin Hopper, Eastman Dental Institute, UK
Ed Boyden         
Massachusetts Institute of Technology, USA

Tools for Seeing and Controlling Biological Systems

Biography: Ed Boyden is a professor of biological engineering and brain and cognitive sciences at the MIT Media Lab and the MIT McGovern Institute. He leads the Synthetic Neurobiology group, which develops tools for analyzing and repairing complex biological systems such as the brain, and applies them systematically to reveal ground truth principles of biological function as well as to repair these systems. These technologies, created often in interdisciplinary collaborations, include expansion microscopy, which enables complex biological systems to be imaged with nanoscale precision, optogenetic tools, which enable the activation and silencing of neural activity with light, and optical, nanofabricated, and robotic interfaces that enable recording and control of neural dynamics. He has launched an award-winning series of classes at MIT that teach principles of neuroengineering, starting with basic principles of how to control and observe neural functions, and culminating with strategies for launching companies in the nascent neurotechnology space. He also co-directs the MIT Center for Neurobiological Engineering, which aims to develop new tools to accelerate neuroscience progress.

Amongst other recognitions, he has received the Breakthrough Prize in Life Sciences (2016), the BBVA Foundation Frontiers of Knowledge Award (2015), the Society for Neuroscience Young Investigator Award (2015), the Carnegie Prize in Mind and Brain Sciences (2015), the Jacob Heskel Gabbay Award (2013), the Grete Lundbeck Brain Prize (2013), the NIH Director's Pioneer Award (2013), the NIH Director's Transformative Research Award (twice, 2012 and 2013), and the Perl/UNC Neuroscience Prize (2011). He was also named to the World Economic Forum Young Scientist list (2013), the Technology Review World’s "Top 35 Innovators under Age 35" list (2006), and his work was included in Nature Methods "Method of the Year" in 2010.

His group has hosted hundreds of visitors to learn how to use new biotechnologies; he also regularly teaches summer courses and workshops in neuroscience, and delivers lectures to the broader public (such as TED in 2011, and the World Economic Forum in 2012, 2013, and 2016). Boyden received his PhD in neurosciences from Stanford University as a Hertz Fellow, where he discovered that the molecular mechanisms used to store a memory are determined by the content to be learned. Before that, he received three degrees in electrical engineering, computer science, and physics from MIT. He has contributed to over 300 peer-reviewed papers, current or pending patents, and articles, and has given over 300 invited talks on his group's work.

 
Aydogan Ozcan                
UCLA, USA

Computational Microscopy, Sensing and Diagnostics

Biography: Dr. Aydogan Ozcan received his Ph.D. degree at Stanford University Electrical Engineering Department. After a short post-doctoral fellowship at Stanford University, he was appointed as a research faculty at Harvard Medical School, Wellman Center for Photomedicine in 2006. Dr. Ozcan joined UCLA in 2007 and he is currently the Chancellor’s Professor at UCLA and an HHMI Professor with the Howard Hughes Medical Institute, leading the Bio- and Nano-Photonics Laboratory at UCLA Electrical Engineering and Bioengineering Departments, and is also the Associate Director of the California NanoSystems Institute (CNSI) at UCLA.

Dr. Ozcan holds 33 issued patents and more than 20 pending patent applications for his inventions in telemedicine, mobile health, nanoscopy, wide-field imaging, lensless imaging, nonlinear optics, fiber optics, and optical coherence tomography. Dr. Ozcan gave more than 35 plenary/keynote talks and 300+ invited talks and is also the author of one book, the co-author of more than 450 peer reviewed publications in major scientific journals and conferences. In addition, Dr. Ozcan is the founder and a member of the Board of Directors of Holomic/Cellmic LLC.

Prof. Ozcan received several major awards including the 2011 Presidential Early Career Award for Scientists and Engineers (PECASE), which is the highest honor bestowed by the United States government on science and engineering professionals in the early stages of their independent research careers. Dr. Ozcan received this prestigious award for developing innovative optical technologies and signal processing approaches that have the potential to make a significant impact in biological science and medicine; addressing public health needs in less developed countries; and service to the optical science community including mentoring and support for underserved minority undergraduate and graduate students. Dr. Ozcan also received the 2015 UCLA Postdoctoral Scholars Mentoring Award for his commitment to training and mentoring of postdoctoral researchers. In addition to these, Dr. Ozcan received the 2015 International Commission for Optics (ICO) Prize, the 2013 SPIE BioPhotonics Technology Innovator Award, the 2011 Army Research Office (ARO) Young Investigator Award, 2011 SPIE Early Career Achievement Award, the 2010 NSF CAREER Award, the 2009 NIH Director’s New Innovator Award, the 2009 Office of Naval Research (ONR) Young Investigator Award, the 2009 IEEE Photonics Society Young Investigator Award and the MIT’s Technology Review TR35 Award for his seminal contributions to near-field and on-chip imaging, and telemedicine based diagnostics.

Prof. Ozcan is also the recipient of the 2016 IEEE Photonics Society Distinguished Lecturer Award, 2013 and 2015 Microscopy Today Innovation Awards, 2012 Popular Science Brilliant 10 Award, 2012 National Academy of Engineering (NAE) The Grainger Foundation Frontiers of Engineering Award, 2011 Innovators Challenge Award presented by the Rockefeller Foundation and mHealth Alliance, the 2010 National Geographic Emerging Explorer Award, the 2010 Bill & Melinda Gates Foundation Grand Challenges Award, the 2010 Popular Mechanics Breakthrough Award, the 2010 Netexplorateur Award given by the Netexplorateur Observatory & Forum in France, the 2011 Regional Health Care Innovation Challenge Award given by The von Liebig Center at UCSD, the 2010 PopTech Science and Public Leaders Fellowship, the 2009 and 2016 Wireless Innovation Award organized by the Vodafone Americas Foundation as well as the 2008 Okawa Foundation Award, given by the Okawa Foundation in Japan.

Prof. Ozcan was selected as one of the top 10 innovators by the U.S. Department of State, USAID, NASA, and NIKE as part of the LAUNCH: Health Forum organized in 2010. He also received the 2012 World Technology Award on Health and Medicine, which is presented by the World Technology Network in association with TIME, CNN, AAAS, Science, Technology Review, Fortune, Kurzweil and Accelerosity.

Dr. Ozcan is elected Fellow of SPIE and OSA, and is a Lifetime Member of AAAS, SPIE and OSA.
 


Congress-wide Plenary Session

Monday, 26 June, 10:00 – 11:00
ICM, Room 1

All attendees are invited to attend this session.

Putting a Spin on Photons 
Jörg Wrachtrup, Univ. of Stuttgart (Germany) 
Efficient matter photon interfaces are key ingredients of quantum technology. Quantum communication relies on photon storage and processing but spin photon interfaces can also increase the sensitivity of quantum sensors. 

Biography: Prof. Dr. Jörg Wrachtrup, who is the head of the 3rd Institute of Physics at the University of Stuttgart, received the first ever Zeiss Research Award this year. He received the Gottfried Wilhelm Leibniz Award for his research work in 2011 and the Max Planck Research Award in 2014.

OSA - The Optical Society

SPIE