Human neutrophil elastase detection with fluorescent peptide sensors conjugated to cellulosic and nanocellulosic materials: part II, structure/function analysis
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- 作者:Krystal R. Fontenot ; J. Vincent Edwards ; David Haldane ; Elena Graves…
- 关键词:Peptides ; Wood cellulose nanocrystals ; Wood nanocellulose composites ; Human neutrophil elastase ; Biosensors
- 刊名:Cellulose
- 出版年:2016
- 出版时间:April 2016
- 年:2016
- 卷:23
- 期:2
- 页码:1297-1309
- 全文大小:3,231 KB
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J. Vincent Edwards (1)
David Haldane (2)
Elena Graves (1)
Michael Santiago Citron (1)
Nicolette T. Prevost (1)
Alfred D. French (1)
Brian D. Condon (1)
1. Southern Regional Research Center, USDA, New Orleans, LA, 70124, USA
2. Innovatech-Engineering, Tallahassee, FL, 32317, USA - 刊物类别:Chemistry and Materials Science
- 刊物主题:Chemistry
Bioorganic Chemistry
Physical Chemistry
Organic Chemistry
Polymer Sciences - 出版者:Springer Netherlands
- ISSN:1572-882X
文摘
Human neutrophil elastase (HNE) is one of a number of proteases that is receiving increased attention as a marker for inflammatory diseases and sensor-based point of care diagnostics. Integral to sensor-based detection is the transducer surface, which is the platform of the sensor’s signal transmittance. Here we describe the bioactivity and related transducer surface properties of cellulose and nanocellulose matrices as peptide–cellulose fluorescent sensors. Detection sensitivity of the sensor signals for HNE levels typically found in chronic wounds is characterized. The fluorescent elastase peptide substrate, Succinamidyl-Ala-Ala-Pro-Val-amidylcoumadin (Pep) was employed in both cellulose and nanocellulose transducer surfaces evaluated for biosensor sensitivity to HNE. The cellulose transducers selected are filter paper (FP) and print cloth (PC) fabric and are comprised of processed cotton fibers. The nanocellulose transducers are the wood cellulose nanocrystals (wCNC) and the wood nanocellulose composites (wNCC). The wNCCs consist of blended quantities of nanocrystalline and microfibrillated cellulose at 66/33 and 50/50, and are characterized as thin films. The biosensor activity was in the order of wCNC-Pep > FP-Pep = NCC-Pep (50/50) > NCC-Pep (66/33) > PC-Pep. Sensor sensitivity correlated with specific surface area. A depiction of peptide substitution on nanocellulosic and cellulosic surfaces is rendered through peptide–cellulose crystallite models derived from X-ray diffraction analysis of the material, and the models discussed in light of biosensor structure activity relationships. In addition, the overall morphology, pore size and porosity of the materials are discussed for their suitability as protease sensors.