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Your search keyword '"Glucksberg, Matthew R."' showing total 8 results
Start Over Author "Glucksberg, Matthew R." Journal analytical chemistry
8 results on '"Glucksberg, Matthew R."'

1. Transcutaneous glucose sensing by surface-enhanced spatially offset Raman spectroscopy in a rat model

Author

Yuen, Jonathan M., Shah, Nilam C., Walsh, Joseph T., Jr., Glucksberg, Matthew R., and Van Duyne, Richard P.

Subjects
Dextrose -- Chemical properties, Dextrose -- Identification and classification, Glucose -- Chemical properties, Glucose -- Identification and classification, Raman spectroscopy -- Methods, Surface chemistry -- Research, Chemistry
Abstract

This letter presents the first quantitative, in vivo, transcutaneous glucose measurements using surface enhanced Raman spectroscopy (SERS). Silver film over nanosphere (AgFON) surfaces were functionalized with a mixed self-assembled monolayer (SAM) and implanted subcutaneously in a Sprague-Dawley rat. The glucose concentration was monitored in the interstitial fluid. SER spectra were collected from the sensor chip through the skin using spatially offset Raman spectroscopy (SORS). The combination of SERS and SORS is a powerful new approach to the challenging problem of in vivo metabolite and drug sensing. 10.1021/ac101951j

Published
2010

2. Lactate and sequential lactate-glucose sensing using surface-enhanced Raman spectroscopy

Author

Shah, Nilam C., Lyandres, Olga, Walsh, Joseph T., Jr., Glucksberg, Matthew R., and Van Duyne, Richard P.

Subjects
Raman spectroscopy -- Usage, Lactates -- Identification and classification, Chemical detectors -- Design and construction, Chemistry
Abstract

Lactate production under anaerobic conditions is indicative of human performance levels, fatigue, and hydration. Elevated lactate levels result from several medical conditions including congestive heart failure, hypoxia, and diabetic ketoacidosis. Real-time detection of lactate can therefore be useful for monitoring these medical conditions, posttrauma situations, and in evaluating the physical condition of a person engaged in strenuous activity. This paper represents a proof-of-concept demonstration of a lactate sensor based on surface-enhanced Raman spectroscopy (SERS). Furthermore, it points the direction toward a multianalyte sensing platform. A mixed decanethiol/mercaptohexanol partition layer is used herein to demonstrate SERS lactate sensing. The reversibility of the sensor surface is characterized by exposing it alternately to aqueous lactate solutions and buffer without lactate. The partitioning and departitioning time constants were both found to be ~30 s. In addition, physiological lactate levels (i.e., 6-240 mg/dL) were quantified in phosphate-buffered saline medium using multivariate analysis with a root-mean-square error of prediction of 39.6 mg/dL. Finally, reversibility was tested for sequential glucose and lactate exposures. Complete partitioning and departitioning of both analytes was demonstrated.

Published
2007

3. In vivo glucose measurement by surface-enhanced Raman spectroscopy

Author

Stuart, Douglas A., Yuen, Jonathan M., Shah, Nilam, Lyandres, Olga, Yonzon, Chanda R., Glucksberg, Matthew R., Walsh, Joseph T., and Van Duyne, Richard P.

Subjects
Raman spectroscopy -- Analysis, Dextrose -- Properties, Dextrose -- Measurement, Glucose -- Properties, Glucose -- Measurement, Optical detectors -- Usage, Chemistry
Abstract

This paper presents the first in vivo application of surface-enhanced Raman scattering (SERS). SERS was used to obtain quantitative in vivo glucose measurements from an animal model. Silver film over nanosphere surfaces were functionalized with a two-component self-assembled monolayer, and subcutaneously implanted in a Sprague--Dawley rat such that the glucose concentration of the interstitial fluid could be measured by spectroscopically addressing the sensor through an optical window. The sensor had relatively low error (RMSEC = 7.46 mg/dL (0.41 mM) and RMSEP = 53.42 mg/dL (2.97 mM).

Published
2006

4. Real-time glucose sensing by surface-enhanced Raman spectroscopy in bovine plasma facilitated by a mixed decanethiol/mercaptohexanol partition layer

Author

Lyandres, Olga, Shah, Nilam C., Yonzon, Chanda Ranjit, Walsh, Joseph T., Jr., Glucksberg, Matthew R., and Van Duyne, Richard P.

Subjects
Dextrose -- Measurement, Dextrose -- Analysis, Dextrose -- Chemical properties, Glucose -- Measurement, Glucose -- Analysis, Glucose -- Chemical properties, Thiols -- Chemical properties, Chemistry
Abstract

A new, mixed decanethiol (DT)/mercaptohexanol (MH) partition layer with dramatically improved properties has been developed for glucose sensing by surface-enhanced Raman spectroscopy. This work represents significant progress toward our long-term goal of a minimally invasive, continuous, reusable glucose sensor. The DT/MH-functionalized surface has greater temporal stability, demonstrates rapid, reversible partitioning and departitioning, and is simpler to control compared to the tri(ethylene glycol) monolayer used previously. The data herein show that this DT/MH-functionalized surface is stable for at least 10 days in bovine plasma. Reversibility is demonstrated by exposing the sensor alternately to 0 and 100 mM aqueous glucose solutions (pH ~7). The difference spectra show that complete partitioning and departitioning occur. Furthermore, physiological levels of glucose in two complex media were quantified using multivariate analysis. In the first system, the sensor is exposed to a solution consisting of water with 1 mM lactate and 2.5 mM urea. The root-mean-squared error of prediction (RMSEP) is 92.17 mg/dL (5.12 mM) with 87% of the validation points falling within the A and B range of the Clarke error grid. In the second, more complex system, glucose is measured in the presence of bovine plasma. The RMSEP is 83.16 mg/dL (4.62 mM) with 85% of the validation points falling within the A and B range of the Clarke error grid. Finally, to evaluate the real-time response of the sensor, the 1/e time constant for glucose partitioning and departitioning in the bovine plasma environment was calculated. The time constant is 28 s for partitioning and 25 s for departitioning, indicating the rapid interaction between the SAM and glucose that is essential for continuous sensing.

Published
2005

5. Glucose sensing using near-infrared surface-enhanced Raman spectroscopy: gold surfaces, 10-day stability, and improved accuracy

Author

Stuart, Douglas A., Yonzon, Chanda Ranjit, Zhang, Xiaoyu, Lyandres, Olga, Shah, Nilam C., Glucksberg, Matthew R., Walsh, Joseph T., and Van Duyne, Richard P.

Subjects
Gold compounds -- Chemical properties, Dextrose -- Research, Glucose -- Research, Raman spectroscopy -- Usage, Chemistry
Abstract

This research presents the achievement of significant milestones toward the development of a minimally invasive, continuously monitoring, glucose-sensing platform based on the optical quantitation of glucose in interstitial fluid. We expand our initial successes in the measurement of glucose by surface-enhanced Raman scattering (SERS), demonstrating substantial improvements not only in the quality and optical properties of the substrate system itself but also in the robusmess of the measurement methodology and the amenability of the technique to compact, diode laser-based instrumentation. Herein, we compare the long-term stability of gold to silver film over nanosphere (AuFON, AgFON) substrates functionalized with a partitioning self-assembled monolayer (SAM) using both electrochemical and SERS measurements. AuFONs were found to be stable for a period of at least 11 days. The switch to AuFONs not only provides a more stable surface for SAM formation but also yields better chemometric results, with improved calibration and validation over a range of 0.5-44 mM (10-800 mg/dL). Measured values for glucose concentrations in phosphate-buffered saline (pH ~7.4) based on 160 independent SERS measurements on AuFONs have a root-mean-square error of prediction of 2.7 mM (49.5 mg/dL), with 91% of the values falling within an extended A-B range on an expanded Clarke error grid. Furthermore, AuFONs exhibit surface plasmon resonances at longer wavelengths than similar AgFONs, which make them more efficient for SERS at near-infrared wavelengths, enabling the use of low-power diode lasers in future devices.

Published
2005

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