Stephen Arnold (scientist)

Last updated
Stephen Arnold
Professor Stephen Arnold.jpg
Born
New York City
NationalityAmerican
Education City University of New York, University of Toledo
Occupation(s)Professor of Physics and Chemical Engineering
Organization NYU Tandon School of Engineering

Stephen Arnold is a Professor of Physics and Chemical Engineering and the Thomas Potts Professor of Physics at the NYU Tandon School of Engineering. [1] He is also an Othmer-Potts Senior Faculty Fellow. The focus of Arnold's research is developing ultra-sensitive bio-sensors and detection of single bio-nanoparticles from virus down to single protein molecules, using Whispering-gallery wave bio-sensors. [2]

Contents

Education

Arnold holds a Bachelor of Science in engineering physics in 1964 from the University of Toledo and a Ph.D. in physics from the City University of New York [ which? ] in 1970. [3]

Career

Arnold worked at the Ecole Normale Superieure, Paris, from March 1972 to September 1973. In 1981, he was named a fellow of the Alfred P. Sloan Foundation. Arnold was a Chevron distinguished visiting professor at the California Institute of Technology from February 1985 to May 1985. In 1986, he was awarded the Sigma Xi Award for Distinguished Scientific Research. In 1988, he became a Fellow of the Optical Society of America. He worked at the Aerospace Corporation as a technical staff member from February 1990 to May 1990 and became a Fellow of the American Physical Society in 1990. In 1994, he received the Outstanding Publication Award at Oak Ridge National Laboratory. Arnold was a visiting scholar at the University of Tokyo from February 1997 to May 1997. [3] In 2000, The University of Toledo awarded him the John J. Turin Award for Outstanding Career Accomplishments in Physics. [4]

Arnold became director of the Othmer Institute for Interdisciplinary Research at NYU Polytechnic July 2003. [5] In February 2009, he was issued a patent from a filing in March 2002 for Detecting and/or Measuring Substance based on Resonance Shifts (of Photons Orbiting within a Microsphere). [6] He was a vising scholar at Harvard University from January until June 2013. [3] Arnold is a University Professor of Physics and Chemical Engineering at the NYU Polytechnic School of Engineering and is the Thomas Potts Professor of physics. [1]

A simplified model of the resonance shift seen if a particle contacts the surface of the sensor Whispering-gallery-mode biosensing.gif
A simplified model of the resonance shift seen if a particle contacts the surface of the sensor

Research

Arnold's research has focused on label-free detection of bio-nanoparticles from the perturbation of the resonant frequency of a microcavity, after estimating the extreme sensitivity of such an approach for DNA sensing in a 2001 American Scientist article. [7] In 2003, he and his co-workers identified the mechanism for the detection of individual protein and viruses. [8] The recipe for the detection and sizing of single HIV viruses following this mechanism was proposed early in 2008 at a Faraday Discussion of the Royal Society of Chemistry. [9] Later that year, this recipe was applied to the detection and sizing of comparably sized single Influenza virus particles. [10] This research is funded by the National Science Foundation. [11] Researchers led by Arnold demonstrated the detection and sizing of the smallest individual RNA virus. [12] They developed the Whispering Gallery-Mode Biosensor, [13] an ultra-sensitive biosensor [2] based on their original proposal and patent application. An additional discovery by co-researcher S.I. Shopova that gold nano-receptors on the microcavity lead to a further frequency shift enhancement led to another patent issued in 2013, from a filing in 2011. [14] This hybrid sensor uses gold nano-antennas on a small glass sphere to detect single ultra-small virus particles as well as individual proteins. [15] Arnold and his team have detected single thyroglobulin molecules, a human cancer marker protein, and single serum albumin molecules, a bovine plasma protein. [16] [17]

Selected publications

Related Research Articles

<span class="mw-page-title-main">Electrophysiology</span> Study of the electrical properties of biological cells and tissues.

Electrophysiology is the branch of physiology that studies the electrical properties of biological cells and tissues. It involves measurements of voltage changes or electric current or manipulations on a wide variety of scales from single ion channel proteins to whole organs like the heart. In neuroscience, it includes measurements of the electrical activity of neurons, and, in particular, action potential activity. Recordings of large-scale electric signals from the nervous system, such as electroencephalography, may also be referred to as electrophysiological recordings. They are useful for electrodiagnosis and monitoring.

<span class="mw-page-title-main">Fluorescent tag</span>

In molecular biology and biotechnology, a fluorescent tag, also known as a fluorescent label or fluorescent probe, is a molecule that is attached chemically to aid in the detection of a biomolecule such as a protein, antibody, or amino acid. Generally, fluorescent tagging, or labeling, uses a reactive derivative of a fluorescent molecule known as a fluorophore. The fluorophore selectively binds to a specific region or functional group on the target molecule and can be attached chemically or biologically. Various labeling techniques such as enzymatic labeling, protein labeling, and genetic labeling are widely utilized. Ethidium bromide, fluorescein and green fluorescent protein are common tags. The most commonly labelled molecules are antibodies, proteins, amino acids and peptides which are then used as specific probes for detection of a particular target.

A biosensor is an analytical device, used for the detection of a chemical substance, that combines a biological component with a physicochemical detector. The sensitive biological element, e.g. tissue, microorganisms, organelles, cell receptors, enzymes, antibodies, nucleic acids, etc., is a biologically derived material or biomimetic component that interacts with, binds with, or recognizes the analyte under study. The biologically sensitive elements can also be created by biological engineering. The transducer or the detector element, which transforms one signal into another one, works in a physicochemical way: optical, piezoelectric, electrochemical, electrochemiluminescence etc., resulting from the interaction of the analyte with the biological element, to easily measure and quantify. The biosensor reader device connects with the associated electronics or signal processors that are primarily responsible for the display of the results in a user-friendly way. This sometimes accounts for the most expensive part of the sensor device, however it is possible to generate a user friendly display that includes transducer and sensitive element. The readers are usually custom-designed and manufactured to suit the different working principles of biosensors.

<span class="mw-page-title-main">Optical ring resonators</span>

An optical ring resonator is a set of waveguides in which at least one is a closed loop coupled to some sort of light input and output. The concepts behind optical ring resonators are the same as those behind whispering galleries except that they use light and obey the properties behind constructive interference and total internal reflection. When light of the resonant wavelength is passed through the loop from the input waveguide, the light builds up in intensity over multiple round-trips owing to constructive interference and is output to the output bus waveguide which serves as a detector waveguide. Because only a select few wavelengths will be at resonance within the loop, the optical ring resonator functions as a filter. Additionally, as implied earlier, two or more ring waveguides can be coupled to each other to form an add/drop optical filter.

<span class="mw-page-title-main">Surface plasmon resonance</span> Physical phenomenon of electron resonance

Surface plasmon resonance (SPR) is a phenomenon that occurs where electrons in a thin metal sheet become excited by light that is directed to the sheet with a particular angle of incidence, and then travel parallel to the sheet. Assuming a constant light source wavelength and that the metal sheet is thin, the angle of incidence that triggers SPR is related to the refractive index of the material and even a small change in the refractive index will cause SPR to not be observed. This makes SPR a possible technique for detecting particular substances (analytes) and SPR biosensors have been developed to detect various important biomarkers.

<span class="mw-page-title-main">Surface-enhanced Raman spectroscopy</span> Spectroscopic technique

Surface-enhanced Raman spectroscopy or surface-enhanced Raman scattering (SERS) is a surface-sensitive technique that enhances Raman scattering by molecules adsorbed on rough metal surfaces or by nanostructures such as plasmonic-magnetic silica nanotubes. The enhancement factor can be as much as 1010 to 1011, which means the technique may detect single molecules.

<span class="mw-page-title-main">Biointerface</span>

A biointerface is the region of contact between a biomolecule, cell, biological tissue or living organism or organic material considered living with another biomaterial or inorganic/organic material. The motivation for biointerface science stems from the urgent need to increase the understanding of interactions between biomolecules and surfaces. The behavior of complex macromolecular systems at materials interfaces are important in the fields of biology, biotechnology, diagnostics, and medicine. Biointerface science is a multidisciplinary field in which biochemists who synthesize novel classes of biomolecules cooperate with scientists who have developed the tools to position biomolecules with molecular precision, scientists who have developed new spectroscopic techniques to interrogate these molecules at the solid-liquid interface, and people who integrate these into functional devices. Well-designed biointerfaces would facilitate desirable interactions by providing optimized surfaces where biological matter can interact with other inorganic or organic materials, such as by promoting cell and tissue adhesion onto a surface.

Magnetic nanoparticles (MNPs) are a class of nanoparticle that can be manipulated using magnetic fields. Such particles commonly consist of two components, a magnetic material, often iron, nickel and cobalt, and a chemical component that has functionality. While nanoparticles are smaller than 1 micrometer in diameter, the larger microbeads are 0.5–500 micrometer in diameter. Magnetic nanoparticle clusters that are composed of a number of individual magnetic nanoparticles are known as magnetic nanobeads with a diameter of 50–200 nanometers. Magnetic nanoparticle clusters are a basis for their further magnetic assembly into magnetic nanochains. The magnetic nanoparticles have been the focus of much research recently because they possess attractive properties which could see potential use in catalysis including nanomaterial-based catalysts, biomedicine and tissue specific targeting, magnetically tunable colloidal photonic crystals, microfluidics, magnetic resonance imaging, magnetic particle imaging, data storage, environmental remediation, nanofluids, optical filters, defect sensor, magnetic cooling and cation sensors.

A nanolaser is a laser that has nanoscale dimensions and it refers to a micro-/nano- device which can emit light with light or electric excitation of nanowires or other nanomaterials that serve as resonators. A standard feature of nanolasers includes their light confinement on a scale approaching or suppressing the diffraction limit of light. These tiny lasers can be modulated quickly and, combined with their small footprint, this makes them ideal candidates for on-chip optical computing.

<span class="mw-page-title-main">Bio-layer interferometry</span> Optical biosensing technology

Bio-layer interferometry (BLI) is an optical biosensing technology that analyzes biomolecular interactions in real-time without the need for fluorescent labeling. Alongside Surface Plasmon Resonance, BLI is one of few widely available label-free biosensing technologies, a detection style that yields more information in less time than traditional processes. The technology relies on the phase shift-wavelength correlation created between interference patterns off of two unique surfaces on the tip of a biosensor. BLI has significant applications in quantifying binding strength, measuring protein interactions, and identifying properties of reaction kinetics, such as rate constants and reaction rates.

Interferometric reflectance imaging sensor (IRIS), formerly known as the spectral reflectance imaging biosensor (SRIB), is a system that can be used as a biosensing platform capable of high-throughput multiplexing of protein–protein, protein–DNA, and DNA–DNA interactions without the use of any fluorescent labels. The sensing surface is prepared by robotic spotting of biological probes that are immobilized on functionalized Si/SiO2 substrates. IRIS is capable of quantifying biomolecular mass accumulated on the surface.

<span class="mw-page-title-main">Whispering-gallery wave</span> Wave that can travel around a concave surface

Whispering-gallery waves, or whispering-gallery modes, are a type of wave that can travel around a concave surface. Originally discovered for sound waves in the whispering gallery of St Paul's Cathedral, they can exist for light and for other waves, with important applications in nondestructive testing, lasing, cooling and sensing, as well as in astronomy.

Photonic molecules are a form of matter in which photons bind together to form "molecules". They were first predicted in 2007. Photonic molecules are formed when individual (massless) photons "interact with each other so strongly that they act as though they have mass". In an alternative definition, photons confined to two or more coupled optical cavities also reproduce the physics of interacting atomic energy levels, and have been termed as photonic molecules.

<span class="mw-page-title-main">Chemiresistor</span> Material with changing electrical resistance according to its surroundings

A chemiresistor is a material that changes its electrical resistance in response to changes in the nearby chemical environment. Chemiresistors are a class of chemical sensors that rely on the direct chemical interaction between the sensing material and the analyte. The sensing material and the analyte can interact by covalent bonding, hydrogen bonding, or molecular recognition. Several different materials have chemiresistor properties: semiconducting metal oxides, some conductive polymers, and nanomaterials like graphene, carbon nanotubes and nanoparticles. Typically these materials are used as partially selective sensors in devices like electronic tongues or electronic noses.

<span class="mw-page-title-main">Bio-FET</span> Type of field-effect transistor

A field-effect transistor-based biosensor, also known as a biosensor field-effect transistor, field-effect biosensor (FEB), or biosensor MOSFET, is a field-effect transistor that is gated by changes in the surface potential induced by the binding of molecules. When charged molecules, such as biomolecules, bind to the FET gate, which is usually a dielectric material, they can change the charge distribution of the underlying semiconductor material resulting in a change in conductance of the FET channel. A Bio-FET consists of two main compartments: one is the biological recognition element and the other is the field-effect transistor. The BioFET structure is largely based on the ion-sensitive field-effect transistor (ISFET), a type of metal–oxide–semiconductor field-effect transistor (MOSFET) where the metal gate is replaced by an ion-sensitive membrane, electrolyte solution, and reference electrode.

Surface plasmon resonance microscopy (SPRM), also called surface plasmon resonance imaging (SPRI), is a label free analytical tool that combines the surface plasmon resonance of metallic surfaces with imaging of the metallic surface. The heterogeneity of the refractive index of the metallic surface imparts high contrast images, caused by the shift in the resonance angle. SPRM can achieve a sub-nanometer thickness sensitivity and lateral resolution achieves values of micrometer scale. SPRM is used to characterize surfaces such as self-assembled monolayers, multilayer films, metal nanoparticles, oligonucleotide arrays, and binding and reduction reactions. Surface plasmon polaritons are surface electromagnetic waves coupled to oscillating free electrons of a metallic surface that propagate along a metal/dielectric interface. Since polaritons are highly sensitive to small changes in the refractive index of the metallic material, it can be used as a biosensing tool that does not require labeling. SPRM measurements can be made in real-time, such as measuring binding kinetics of membrane proteins in single cells, or DNA hybridization.

Brian T. Cunningham is an American engineer, researcher and academic. He is a Donald Biggar Willett Professor of Engineering at University of Illinois at Urbana-Champaign. He is a professor of Electrical and Computer Engineering, and a professor of Bioengineering.

Ester H. Segal is an Israeli nanotechnology researcher and professor in the Department of Biotechnology and Food Engineering at the Technion - Israel Institute of Technology, where she heads the Laboratory for Multifunctional Nanomaterials. She is also affiliated with the Russell Berrie Nanotechnology Institute at the Technion - Israel Institute of Technology. Segal is a specialist in porous silicon nanomaterials, as well as nanocomposite materials for active packaging technologies to extend the shelf life of food.

Photonic crystal sensors use photonic crystals: nanostructures composed of periodic arrangements of dielectric materials that interact with light depending on their particular structure, reflecting lights of specific wavelengths at specific angles. Any change in the periodicity or refractive index of the structure can give rise to a change in the reflected color, or the color perceived by the observer or a spectrometer. That simple principle makes them useful colorimetric intuitive sensors for different applications including, but not limited to, environmental analysis, temperature sensing, magnetic sensing, biosensing, diagnostics, food quality control, security, and mechanical sensing. Many animals in nature such as fish or beetles employ responsive photonic crystals for camouflage, signaling or to bait their prey. The variety of materials utilizable in such structures ranging from inorganic, organic as well as plasmonic metal nanoparticles makes these structures highly customizable and versatile. In the case of inorganic materials, variation of the refractive index is the most commonly exploited effect in sensing, while periodicity change is more commonly exhibited in polymer-based sensors. Besides their small size, current developments in manufacturing technologies have made them easy and cheap to fabricate on a larger scale, making them mass-producible and practical.

<span class="mw-page-title-main">MicroRNA biosensors</span> Review of microRNA biosensors

MicroRNA (miRNA) biosensors are analytical devices that involve interactions between the target miRNA strands and recognition element on a detection platform to produce signals that can be measured to indicate levels or the presence of the target miRNA. Research into miRNA biosensors shows shorter readout times, increased sensitivity and specificity of miRNA detection and lower fabrication costs than conventional miRNA detection methods.

References

  1. 1 2 "A nanoplasmonic sensor detects cancer proteins at the single-molecule level". SPIE. September 30, 2013. Retrieved September 14, 2015.
  2. 1 2 David Szondy (August 28, 2012). ""Whispering gallery" biosensor detects the smallest viruses". Giz Mag. Retrieved September 14, 2015.
  3. 1 2 3 "Stephen Arnold | NYU-Poly". Poly.edu. 2009-02-17. Retrieved 2012-11-20.
  4. "John J. Turin Award and Convocation". University of Toledo. Retrieved September 14, 2015.
  5. "Researchers set record for detecting smallest virus, opening possibilities for early disease detection". Phys.org. August 28, 2012. Retrieved September 14, 2015.
  6. S. Arnold; I. Teraoka. "Patent US7491491 - Detecting and/or measuring a substance based on a resonance shift of photons ... - Google Patents" . Retrieved 2012-11-20.
  7. Stephen Arnold (2001). "Microspheres, Photonic Atoms and the Physics of Nothing". American Scientist. 89 (5): 414–421. Bibcode:2001AmSci..89..414A. doi:10.1511/2001.5.414.
  8. S. Arnold; M. Khoshsima; I. Teraoka; S. Holler; F. Vollmer (2003). "Shift of whispering gallery modes in microspheres by protein adsorption". Optics Letters. 28 (4): 272–274. Bibcode:2003OptL...28..272A. doi:10.1364/ol.28.000272. PMID   12653369.
  9. S. Arnold; R. Ramjit; D. Keng; V. Kolchenko; I. Teraoka (2008). "MicroParticle PhotoPhysics Illuminates Viral Biosensing". Faraday Discussions. 137: 65–83. Bibcode:2008FaDi..137...65A. doi:10.1039/b702920a. PMID   18214098.
  10. F. Vollmer; S. Arnold & D. Keng (December 2008). "Single virus detection from the reactive shift of a whispering-gallery mode". PNAS. 105 (52): 20701–4. Bibcode:2008PNAS..10520701V. doi: 10.1073/pnas.0808988106 . PMC   2603258 . PMID   19075225.
  11. "Groundbreaking research leads to detection of smallest virus particle, implications for early treatment of disease". Phys.org. December 19, 2012. Retrieved September 14, 2015.
  12. V. R. Dantham; S. Holler; V. Kolchenko; Z. Wan & S. Arnold (July 2012). "Taking whispering gallery-mode single virus detection and sizing to the limit". Applied Physics Letters. 101 (4): 043704. Bibcode:2012ApPhL.101d3704D. doi:10.1063/1.4739473.
  13. F. Vollmer & S. Arnold (2008). "Whispering-gallery-mode-biosensing: label-free sensing down to single molecules". Nature Methods. 5 (7): 591–596. doi:10.1038/nmeth.1221. PMID   18587317. S2CID   8277240.
  14. S.I. Shopova; S. Arnold; R.H. Rajmangal. "Patent US8493560 - Plasmonic enhancement of Whispering Gallery Mode Biosensors" . Retrieved September 14, 2015.
  15. Marsha Lewis (July 25, 2013). "Exposing the Smallest Viruses". Inside Science. Retrieved September 14, 2015.
  16. James Devitt (July 20, 2013). "Sensor detects Incredibly Small Cancer Marker". Futurity. Retrieved September 14, 2015.
  17. V. R. Dantham; S. Holler; C. Barbre; D. Keng; V. Kolchenko; S. Arnold (2013). "Label-free detection of single protein using a nanoplasmonic-photonic hybrid microcavity" (PDF). Nano Letters. 13 (7): 3347–51. Bibcode:2013NanoL..13.3347D. doi:10.1021/nl401633y. PMID   23777440.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.