Employment Application - Md Anderson Cancer Center: Fill & Download for Free

It depends on the job and on your current status at your university. I would say that it would only be appropriate to include things from high school during your freshman year of college as you have not yet established yourself fully as a member of your university. It takes time to build up a college resume!By the time you become a sophomore in college, you have an entire year’s worth of college coursework, extracurriculars, work experience, etc. To include in your future job applications, hence your high school qualifications become less important. Employers care about your most recent endevours, so show them that you are an active member of your college by taking classes and participating in extracurricular activities that will show them you are interested in their line of work and that you have the qualifications necessary to succeed.For example, I am currently a graduate student at MD Anderson Cancer Center pursuing an MS in Cancer Biology. When I applied to this program, I made sure to emphasize my previous research experiences, teaching assistantships, and research related mentorship activities. These activities showed knowledge of what to expect in graduate school and the potential to contribute to the great research going on there.Overall, keep the high school stuff only until you feel that you have enough college stuff to replace it. This should not take more than one year if you are actively pursuing opportunities to further your career at university.

Data abuses in today's culture are becoming more common. Hackers are aware that they will sell stolen data on the Dark Web or use them for extortion purposes.However, data security encryption technology is popular. It requires the security of cryptographic information by way of scrambling code. Just people can read the data with the key to decryption.Seven Reasons to Rely on Encryption Technologies are as Follows :1. It Can Be Found in a Variety of DevicesOne of the main benefits of advanced encryption is that you can use it on any or most technical gadgets. Data on an iPhone can be encrypted as long as you use the password or touch recognition option to secure it. In the Configuration portion of the Protection menu, an Android phone makes it simple to go through an encoding process. There are also Android smartphones that can be encrypted when you buy them.Free and paid device encryption solutions are also available. Companies have complete or file-based encryption, depending on the needs. Furthermore, do not forget the options available on an SD card or thumb drive to encrypt content. Since people who want to encrypt their data have many options, it is worth at least looking at which solutions are ideal for you. It is therefore essential to encrypt Internet traffic. The 256-bit encryption standard is often used by most stable VPN providers.Encryption of multi-displays is also increasing as SMS marketing is getting more prevalent. The demand for SMS marketing is expected to grow by 20,5% per year from 2019 to 2025 in a report by Grandview Research. In order to contact their clients, a rising number of businesses use text messaging.2. You will Help Escape Regulatory PenaltiesData security encoding technologies can become mandatory rather than voluntary, depending on your sector or the particular policies outlined by your employer. For instance, patient privacy regulations in the health care industry demand that information be kept encrypted. The non-compliance penalties for organisations is substantial.In one of the cases in June 2018, the MD Anderson Cancer Center of the University of Texas paid a settlement of $4.3 million for breaking the Portability and Transparency Rule, most generally referred to as HIPAA. In 2012, the crisis started when a gunman stole a laptop from an employee's home with 30 000 medical files. In the same year as in 2013, two distinct instances of additional data loss were observed from misplaced USB drives.The data-containing machines have not been encrypted. When he gave the sentence, the judge who ruled the case raised this apparent oversight. Regulatory fines are genuine issues both in health care and other sectors that also process confidential information. Apart from the fact such events can slash the rewards of a company, poor ads can cause consumers to wonder about doing business with businesses who do not store data safely.3. It Will Allow You to be More Safe While Operating RemotelyCompanies often need staff most often to use encrypted smartphones simply because of such accidents. This is not shocking and other technology developments help people remain productive everywhere. It's not surprising.But the majority of company managers agree that privacy infringements are greater as people work remotely in a 2018 North American report released by Shred-It. In fact, 86% of C-Suite administrators and 60% of small business owners hold this belief. If you work remotely all the time or just sometimes, data encryption allows you to avoid misrepresentation.4. Data Integrity SupportAnother factor that should be noted with respect to data security encryption technology is that it serves to boost privacy integrity alone. Cryption does not, in practice, guarantee this alone, but as part of an overall plan it is something you should and can do. If you have faith in the results, it is easier to make choices in confidence.Statistics reveal that insufficient data consistency is the main explanation for the inability to produce the desired outcomes for 40% of all company initiatives. High-quality data will help you discover more about your clients, track patterns and otherwise figure out information that could be lacking. Companies also use methods such as data purification to enhance consistency, which is a positive beginning.The encryption of data may help ensure that an analysis is performed only by appropriate parties. It also eliminates the risk of a hacker exploiting data effectively and unnoticing such actions.5- Data Encryption is a Confidentiality DefenseThink your mobile or computer details and you can possibly see that encryption secures your identity along with your data. For example, encryption applications on a mobile will prohibit any unauthorized party from accessing your information, or at least extraordinarily challenging it. In certain occasions, the analysis of phone records on encrypted smartphones was challenging for law enforcement officers.Data protection will avoid confidential information from existing un-knowngly on the internet for regular users who do not normally care about their phones being evidence. When hackers compromise details including email addresses, the legitimate owners will not know until months have passed what has happened.To grasp how severe abuses of privacy can occur, remember the recent case in which over 770 million email addresses and passwords were revealed to hackers. The scientist for cryptography, who found out that the information is actually attributable to multiple particular infringements of data rather than a massive settlement.Nevertheless, the sheer number of uncovered variations of e-mail/password suffices to show how powerful hackers can access knowledge. It's also scary that hackers get more imaginative with the use they make of confiscated records. Some of them personify doctors after obtaining medical license details. Some flight miles also fly and use them for illegal sales of flight fares.6. Might have a Strategic Edge in Data EncryptionSince data encryption extends to all information at leisure and in transport, it gives reliable security that can give people who process information peace of mind.Studies indicate that a rising majority of companies know that it is important to establish an encryption strategy. A research presented in 2019 by the Ponemon Institute showed that 45 per cent of the businesses surveyed indicated that they regularly implemented a complete encryption policy in their organisations throughout the financial year 2018. Less (42%) listed a restricted encryption technique for those programs or data forms.Just 13% said they had no plan whatsoever. This analysis shows that the business may be lagging behind rivals if it fails to emphasize encryption. The positive news is that there is a rising demand for encryption tools.Grand View Research's industry forecast analyzed the encryption software market and offered a forecast for the 2019-2025 period. For the defined time period, the organization expects a cumulative average growth rate (CAGR) of 16.8%, with on-site benefits mainly as cloud-based options begin to expand.7. Encryption Technologies Could Improve Trust Data SecurityWhile certain businesses are not forced to encrypt data because of privacy laws, they decide to do so to illustrate that their customers take privacy seriously. The statement is especially important because of the loss of faith in many people on the Internet.53% of respondents said they were now more concerned with online privacy than a year earlier, according to the 2019 CIGI-Ipsos World Survey on Internet Security and Trust. The same study found that almost half of those surveyed (49 percent) claimed they had less personal information online because of their fear of the internet. Surprisingly, only 19% of surveyed respondents said they used more encryption to improve security.These results offer businesses an ability to improve consumer confidence by explaining clearly how customer data are encrypted. While end users may still take ownership, businesses will enhance their integrity by underlining their willingness to implement the new encryption technology.

Q. Which school is better for a PhD in CS or engineering, Rice University or Johns Hopkins (something related to medical engineering)?A. Both Rice and JHU have superb bioengineering graduate programs, with JHU earning the top rank on the US News survey. Rice holds the edge with its BRC | BioScience Research Collaborative, working closely with the adjacent world’s largest Texas Medical Center provides for unlimited opportunity to expand Rice’s global reach and build unparalleled teaching and research programs. Rather than choosing the institution, the PhD candidate should search for particular individuals in his/her field of research interest as potential advisor and mentor.BioScience Research Collaborative Institutes & CentersMedical Futures LabRice Shared Equipment Authority (SEA)Rice 360: Institute for Global Health TechnologiesKinder Institute for Urban ResearchThe Gulf Coast Consortia (GCC)The Institute of Biosciences and BioengineeringThe National Space Biomedical Research Institute (NSBRI)The Center for Space Medicine (CSM)Children's Environmental Health Initiative (CEHI) The Center for Theoretical Biological Physics (CTBP)Texas Medical Center - Leader in Collaborative Medicine and ResearchBiomedical Engineering / BioengineeringRanked in 2017, part of Best Engineering SchoolsBiomedical engineers and bioengineers apply their knowledge of life sciences and technology to solve problems that affect life on Earth. These are the top engineering schools for graduate biomedical / bioengineering degrees. Each school's score reflects its average rating on a scale from 1 (marginal) to 5 (outstanding), based on a survey of academics at peer institutions.What is Biomedical Engineering?Deeply interdisciplinary, biomedical engineering applies modern approaches from the experimental life sciences in conjunction with theoretical and computational methods from engineering, mathematics and computer science to the solution of biomedical problems of fundamental importance, such as human health.Why Hopkins?Ranked as the nation’s top program by U.S. News & World Report, Johns Hopkins’ biomedical engineering department affords students the opportunity to work closely – from freshmen year on – with 33 primary faculty members who are world leaders in their respective fields, including medical imaging, computational biology, bioinformatics, imaging science, biomaterials, cell and tissue engineering and microsystems. Alongside these faculty members, students engage in top-level research at the School of Medicine. Working as part of design teams, students develop much-needed therapies and devices from concept to prototype, and some even commercialize their inventions. An industrial liaison office also fosters interaction between Hopkins biomedical engineering teams and industry, resulting in exciting collaboration and employment opportunities.Department of Biomedical EngineeringResearch Centers and ProgramsThe interdisciplinary nature of biomedical engineering has been a key factor in the establishment of a number of interdepartmental research programs, centers, and institutes at Johns Hopkins. All of these centers and programs provide comprehensive research opportunities.Related Centers & InstitutesApplied Physics LaboratoryCenter for Bioengineering Innovation and DesignCenter for Hearing and BalanceCenter for Imaging ScienceCenter for Magnetic Resonance Micro-ImagingInstitute for Computational MedicineMind Brain InstituteTransitional Tissue Engineering CenterSee all news storiesReversing the Loss of SightJamie Spangler joins BME facultyCBID designs automated mosquito trap to track ZikaLearning the science behind imaging devicesJohns Hopkins Coulter Translational PartnershipCenter for Bioengineering Innovation and DesignBME Design StudioIndustrial LiaisonBME EDGEPhD programFaculty directoryResearch LabsNewsletterJohns HopkinsDepartment of Biomedical Engineering720 Rutland AvenueBaltimore, MD 21205Rice University Department of BioengineeringThe Rice University Department of Bioengineering is a top-tier teaching and research institution with a faculty committed to excellence in education, interdisciplinary, basic and translational research. Key to our success as an international leader in bioengineering is capitalizing on Rice's location, which promotes the development of long-term strategic partnerships with experts in industry and academic and government institutions. Rice is situated in the midst of one of the largest, most diverse cities in the nation. Our neighbors include the Texas Medical Center (TMC) and its member institutions. The TMC, which is the largest medical center in the world, provides unlimited opportunity to expand our global reach and build unparalleled teaching and research programs that solve a broad spectrum of complex problems in science and medicine. There is also close association with NASA.Rice IBB | IBBOur distinguished faculty members have diverse research interests focused on establishing engineering principles and developing cutting-edge technologies to solve a host of life-science problems in:Biomaterials and Drug Delivery,Biomedical Imaging and Diagnostics,Cellular and Bimolecular Engineering,Computational and Theoretical Bioengineering,Systems and Synthetic Biology, andTissue Engineering and Biomechanics.Rice BIOE NewsThere are close industrial ties between Rice and Commercial Entities. There is continuing student recognition including numerous NSF fellowship awards.Rice University | Virtual ToursPeople SpotlightAmina A. QutubAssistant Professor of BioengineeringSystems Biology LaboratoryPostdoctoral Fellow, Biomedical Engineering,Johns Hopkins University School of Medicine (2004-2009)Ph.D., Bioengineering, University of California, Berkeley/San Francisco (2004)B.S., Chemical Engineering, cum laude, Rice University (1999)Qutub integrates integrates biological systems modeling theory and design to characterize hypoxic response signaling and neurovascular dynamics. »Antonios G. MikosLouis Calder Professor of Bioengineering, Chemical and Biomolecular EngineeringDirector, Center for Excellence in Tissue EngineeringDirector, J.W. Cox Laboratory for Biomedical EngineeringMikos Research GroupPostdoctoral Fellow Massachusetts Institute of Technology, Harvard Medical School (1990-1991)Ph.D., Chemical Engineering, Purdue University (1988)M.S.Ch.E., Chemical Engineering, Purdue University (1985)Dipl.ChE., Chemical Engineering, Aristotle University of Thessaloniki, Greece (1983)Mikos’ research focuses on the synthesis, processing, and evaluation of new biomaterials for use as scaffolds for tissue engineering, as carriers for controlled drug delivery, and as non-viral vectors for gene therapy. »Bilal GhosnLecturerPostdoctoral Fellow, Bioengineering, University of Washington (2009-2013)Ph.D., Biomedical Engineering, University of Texas at Austin (2009)M.S., Biological & Agricultural Engineering, Louisiana State University (2004)B.S., Biological Engineering, Louisiana State University (2002)Bilal Ghosn is an instructor for several project-based laboratory modules and engineering courses for Rice's bioengineering program. »David Yu ZhangTed Law Jr. Assistant Professor of BioengineeringNucleic Acid Bioengineering Laboratory (NABLab)Postdoctoral Fellow, Wyss Institute for Biologically Inspired Engineering,Harvard Medical School (2010-2013)Ph.D. Computation and Neural Systems, California Institute of Technology (2010)B.S. Biology, California Institute of Technology (2005)Zhang's research involves the systematic modeling and rational design of nucleic acids, engineering designer nucleic acid molecules that enable revolutionary in vitro diagnostics, in situ imaging, tissue engineering, transcription regulation, and materials scaffolding and modulation. »Eric RichardsonLecturerDirector, Global Medical Innovation (GMI) track in the Master of Bioengineering (M.B.E.) programPrincipal R&D Engineer, Medtronic (2011-2013)Senior R&D Engineer, Medtronic (2009-2011)Ph.D., Biomedical Engineering, University of Minnesota (2009)B.S., Mechanical Engineering, Brigham Young University (2005)Richardson brings valuable interdisciplinary industry experience in biomedical engineering research and product development to his role as lecturer. »Gang BaoFoyt Family Professor in BioengineeringDirector, Nanomedicine Center for Nucleoprotein MachinesCPRIT Scholar in Cancer ResearchLaboratory of Biomolecular Engineering and NanomedicinePostdoctoral Fellow, Materials Department, University of California, Santa Barbara (1988-1991)Ph.D., Applied Mathematics, Lehigh University (1987)M.Sc., Applied Mathematics, Shandong University (1981)B.S., Mechanical Engineering, Shandong University (1976)Gang Bao is a pioneer in nanomedicine, molecular imaging, and the emerging area of genome editing. The nanoscale structures and devices engineered in his lab have broad-based applications in basic biological research and in the translation of nano-scale tools for disease diagnostics and treatment. »3 teams of Rice-UTHealth faculty win research grants to study children’s healthHerbert LevineHasselmann Professor of BioengineeringDirector, Center for Theoretical Biological Physics (CTBP)Director, SSPBCPRIT Scholar in Cancer ResearchPostdoctoral Research Fellow, Physics, Harvard University (1979-1982)Ph.D., Physics, Princeton University (1979)M.A., Physics, Princeton University (1977)B.S., Physics, Massachusetts Institute of Technology (1976)Herbert Levine examines the dynamics of non-equilibrium systems, both deterministic and stochastic, to explain and quantify the intricate processes that govern biological systems. He is a pioneer in using theory to expand experimental findings and in the development of well-parameterized computational models. »K. Jane Grande-AllenIsabel C. Cameron Professor of BioengineeringDirector, Institute of Biosciences and Bioengineering (IBB)Integrative Matrix Mechanics LaboratoryPostdoctoral Fellow, Department of Biomedical Engineering,Cleveland Clinic Foundation (1998-2000)Ph.D., Bioengineering, University of Washington (1998)B.A., with top honors, Mathematics and Biology, Transylvania University (1991)Grande-Allen’s research uses engineering analysis to understand and fight heart valve disease. »Rice Engineering LabAssociate Professor of BioengineeringAssociate Professor, Biochemistry and Cell BiologyTabor LaboratoryPostdoctoral Fellow, Department of Pharmaceutical Chemistry,University of California, San Francisco (2006-2010)Ph.D., Molecular Biology, University of Texas (2006)B.A., Biology, University of Texas (2001)Jeff Tabor builds synthetic, genetic, control systems to engineer complex biological behaviors such as pattern formation and social interactions. This research is of interest to basic science and has broad biomedical and industrial applications. »Professor of Bioengineering, Rice UniversityLodwick T. Bolin Professor of Biochemistry,Baylor College of MedicineJianpeng Ma's LaboratoryPostdoctoral Fellow, Computational Biophysics, Harvard University (1996-2000)Ph.D., Chemistry, Boston University (1996)B.S., Physical Chemistry, Fudan University, Shanghai, P.R. China (1985)Jianpeng Ma studies the relationship between structure and function in biological molecules through computational biophysics, structural biology and the development of mathematical algorithms for... »McDevitt Research Labs Rice UniversityJoel L. MoakeSenior Research Scientist andAssociate Director, J.W. Cox Laboratory for Biomedical Engineering, Rice UniversityProfessor of Medicine, Baylor College of MedicineMoake Laboratory in Hematological ResearchM.D., Johns Hopkins University School of Medicine (1967)B.A., Johns Hopkins University (1964)Dr. Joel Moake specializes in platelet function in blood. His lab focus on the molecular events associated with thrombotic thrombocytopenic purpura (TTP) and hemolytic-uremic syndrome (HUS)- especially, the interaction between the adhesive multimeric protein, von Willebrand factor (VWF), and the VWFcleaving metalloprotease enzyme, ADAMTS-13. »Jordan S. MillerAssistant Professor of BioengineeringPostdoctoral Fellow, Department of Bioengineering, University of Pennsylvania (2008-2013)Ph.D., Bioengineering, Rice University (2008)B.S., Biology, minor in Biomedical Engineering, Massachusetts Institute of Technology (2003)Physiologic Systems Engineering and Advanced Materials LaboratoryMiller's expertise in biomaterials and regenerative medicine combines synthetic chemistry, 3D printing, microfabrication, and molecular imaging to direct cultured human cells to form more complex organizations of living vessels and tissues. »Junghae SuhAssociate Professor in BioengineeringSynthetic Virology LaboratoryPostdoctoral Fellow, Laboratory of Genetics, Salk Institute for Biological Studies (2005-2007)Ph.D., Biomedical Engineering, Johns Hopkins School of Medicine (2004)B.S., Chemical Engineering, Massachusetts Institute of Technology (1999)Junghae Suh specializes in designing and investigating gene delivery vectors for various applications in biomedicine. Her Rice laboratory combines broad-based knowledge of protein engineering and molecular/cell biology to engineer the properties of naturally occurring viruses for the treatment of debilitating human diseases. »Ka-Yiu SanE.D. Butcher Professor of BioengineeringProfessor of Chemical and Biomolecular EngineeringMetabolic Engineering and Systems Biotechnology LaboratoryPostdoctoral Fellow, Chemical Engineering, California Institute of Technology (1984)Ph.D., Chemical Engineering, California Institute of Technology (1984)M.S., Chemical Engineering, California Institute of Technology (1981)B.S., Summa Cum Laude, Chemical Engineering, Rice University (1978)Ka-Yiu San applies various chemical and bioengineering processes to discover how biological systems, such as E. coli, can be manipulated and used as catalysts to create useful products. »Z. Maria OdenFull Teaching Professor, BioengineeringDirector, Oshman Engineering Design KitchenPostdoctoral Fellow, Harvard Medical School (1994-1997)Ph.D., Biomedical Engineering, Tulane University (1994)M.S., Biomedical Engineering,Tulane University (1991)B.S.E., Biomedical Engineering, Tulane University (1989)As director of the OEDK and as a full teaching professor of bioengineering, Maria Oden coordinates the technical design efforts of the department, and the Global Health Technologies minor. »Michael W. DeemJohn W. Cox Professor in Biochemical and Genetic EngineeringProfessor, Physics and AstronomyChair, Department of BioengineeringFounding Director, Ph.D. Program in Systems, Synthetic, and Physical Biology (SSPB)Deem GroupPostdoctoral Fellow, Physics, Harvard University (1995-1996)Ph.D., Chemical Engineering, University of California at Berkeley (1994)B.S., with honors, Chemical Engineering, California Institute of Technology (1991)Michael Deem works in the area of evolution, immunology, and materials. He has brought tools from statistical physics to bear on problems in these areas. »Michael R. DiehlAssociate Professor of BioengineeringAssociate Professor of ChemistrySynthetic Biology and Macromolecular Systems Bioengineering GroupBeckman Senior Research Fellow, Chemistry and Chemical Engineering,California Institute of Technology (2002-2005)Ph.D., Physical Chemistry, University of California at Los Angeles (2002)B.S., Chemistry, The College of New Jersey (1997)Michael Diehl uses an interdisciplinary approach to investigate the complex function of proteins when they interact as functional groups. »Oleg A. IgoshinAssociate Professor of BioengineeringCellular Systems Dynamics LabPostdoctoral Fellow, Biomedical Engineering, University of California, Davis (2004-2006)Ph.D., University of California, Berkeley (2004)M.Sc., Chemical Physics, Feinberg Graduate School,Weizmann Institute of Science, Israel (2000)B.Sc., Physics, summa cum laude, Novosibirsk State University, Russia (1998)Oleg Igoshin's work in computational systems biology focuses on evolutionary design principles and the characterization of biochemical networks, pattern formation in bacterial biofilms, and genetic networks in bacterial and stem cell development. »Omid VeisehAssistant Professor of Bioengineering,CPRIT Scholar in Cancer ResearchPostdoctoral Fellow, MIT and Harvard Medical School (2011-2016)Ph.D., Materials Science & Engineering and Nanotechnology, University of Washington (2009)B.S., Cell Biology, Western Washington University (2002)Omid Veiseh’s laboratory focuses on the development, processing, and evaluation of novel platforms of implantable and or injectable technologies for in vivo cell and drug delivery and biochemical sensing. This involves characterizing mechanisms of disease pathology and modulating immune system interactions for improved compatibility to biomaterials. »Rebecca Richards-KortumMalcolm Gillis University ProfessorProfessor of BioengineeringProfessor of Electrical and Computer EngineeringDirector, Rice 360°: Institute for Global HealthFounder, Beyond Traditional BordersOptical Spectroscopy and Imaging LaboratoryPh.D., Medical Physics, Massachusetts Institute of Technology (1990)M.S., Physics, Massachusetts Institute of Technology (1987)B.S., Physics and Mathematics, University of Nebraska - Lincoln (1985)Richards-Kortum combines nanotechnology and molecular imaging with microfabrication technologies to build optical imaging systems that are inexpensive, portable, and provide point-of-care diagnosis. »Rebekah A. DrezekProfessor of BioengineeringProfessor of Electrical and Computer EngineeringAssociate Chair, Department of BioengineeringOptical Molecular Imaging and Nanobiotechnology LaboratoryPostdoctoral Fellow, University of Texas M.D. Anderson Cancer Center (2001-2002)Ph.D., Electrical Engineering, University of Texas at Austin (2001)M.S., Electrical Engineering, University of Texas at Austin (1998)B.S., summa cum laude, Electrical Engineering, Duke University (1996)Rebekah Drezek develops optical molecular imaging technologies for the in vivo assessment of tissue pathology and for the quantitative analysis of nanoparticle uptake and interaction within cellular environments »Renata RamosLecturerDirector, Bioengineering Undergraduate StudiesPostdoctoral Fellow, Department of Bioengineering, Rice University (2008-2010)Ph.D., Biomedical Engineering, University of Arizona (2008)B.S., summa cum laude, Mechanical Engineering, Industrial Engineering / Mechanical Design,Instituto Tecnológico y de Estudios Superiores de Monterrey Chihuahua, México (2002)Renata Ramos is an instructor for several project-based laboratory modules and lecture courses for Rice's bioengineering program and the George R. Brown School of Engineering. »Robert M. RaphaelAssociate Professor, BioengineeringDirector, Bioengineering Graduate StudiesPrincipal Investigator, Rice University/Baylor College of Medicine Neuroengineering IGERTMembrane and Auditory Bioengineering GroupPostdoctoral Fellow, Biomedical Engineering, Johns Hopkins University (1998-2001)Postdoctoral Fellow, Hearing Science, Johns Hopkins University (1996-1998)Ph.D., Biophysics, University of Rochester (1996)M.S., Biophysics, University of Rochester (1992)B.S., Physics/Philosophy, University of Notre Dame (1989)Raphael investigates how the coupling between mechanical, electrical and transport properties of biomembranes regulates cellular processes. The research is producing insights into the causes and treatment of hearing loss and deafness. »Sheng TongSenior Faculty FellowLaboratory of Biomolecular Engineering and NanomedicinePostdoctoral Fellow, Biomedical Engineering, University of California at San Diego (2003-2006)Ph.D., Biomedical Engineering, Duke University (2003)M.S., Mechanical Engineering, Peking University (1998)B.S., Mechanical Engineering, University of Science and Technology of China (1995)Sheng Tong develops nano- technologies for the early detection and treatment of atherosclerosis, cancer and many other human diseases. »Tomasz S. TkaczykAssociate Professor in BioengineeringAssociate Professor in Electrical and Computer EngineeringModern Optical Instrumentation and Bio-imaging LaboratoryPostdoctoral Fellow, Applied Optics, The University of Arizona, Tucson (2002 – 2003)Postdoctoral Fellow, Biomedical Imaging, The University of Arizona, Tucson (2001 – 2002)Ph.D. Optical Engineering and Physical Optics, Optical Engineering Div. of the Institute of Micromechanics & Photonics, Warsaw University of Technology, Warsaw, Poland (2000)MS. Eng. Optical Engineering, Department of Mechatronics, Warsaw University of Technology, Warsaw, Poland (1994)Tkaczyk develops platform optical instruments that combine technologies in optics, opto-mechanics, electronics and software, and bio-chemical materials for the early detection and treatment of disease. »Volker SchweikhardResearch Assistant ProfessorPh.D., Physics, University of Colorado at Boulder (2009)Diplom Physics, University of Stuttgart, Germany (2001)Schweikhard investigates how biological cells communicate to organize and maintain functional tissues and organs, and how these mechanisms fail in disease. »Grant to Rice, Baylor College of Medicine and UT McGovern Medical School to push reconstructive surgery