Quantification of fractional and absolute functionalization of gelatin hydrogels by optimized ninhydrin assay and 1H NMR

Quantification of fractional and absolute functionalization of gelatin hydrogels by optimized ninhydrin assay and 1H NMR

3D cell culture in protein-based hydrogels often begins with chemical functionalization of proteins with cross-linking agents such as methacryloyl or norbornene. An important and variable characteristic of these materials is the degree of functionalization (DoF), which controls the reactivity of the...

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Veröffentlicht in:Analytical and bioanalytical chemistry 2020-09, Vol.412 (24), p.6211-6220
Hauptverfasser: Zatorski, Jonathan M., Montalbine, Alyssa N., Ortiz-Cárdenas, Jennifer E., Pompano, Rebecca R.
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Sprache:eng
Schlagworte:
Amino acids
Analytical Chemistry
Assaying
Biochemistry
Biomaterials
Biomedical materials
Cell culture
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Colorimetry
Crosslinking
Female Role Models in Analytical Chemistry
Food Science
Gelatin
Hydrogels
Laboratory Medicine
Mechanical properties
Monitoring/Environmental Analysis
Ninhydrin
NMR
Nuclear magnetic resonance
Paper in Forefront
Proteins
Quality control
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container_issue 24
container_start_page 6211
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creator Zatorski, Jonathan M.
Montalbine, Alyssa N.
Ortiz-Cárdenas, Jennifer E.
Pompano, Rebecca R.
description 3D cell culture in protein-based hydrogels often begins with chemical functionalization of proteins with cross-linking agents such as methacryloyl or norbornene. An important and variable characteristic of these materials is the degree of functionalization (DoF), which controls the reactivity of the protein for cross-linking and therefore impacts the mechanical properties and stability of the hydrogel. Although 1 H NMR has emerged as the most accurate technique for quantifying absolute DoF of chemically modified proteins, colorimetric techniques still dominate in actual use and may be more useful for quantifying fractional or percent DoF. In this work, we sought to develop an optimized colorimetric assay for DoF of common gelatin-based biomaterials and validate it versus NMR; along the way, we developed a set of best practices for both methods and considerations for their most appropriate use. First, the amine-reactive ninhydrin assay was optimized in terms of solvent properties, temperature, ninhydrin concentration, and range of gelatin standards. The optimized assay produced a linear response to protein concentration in a convenient, 96-well plate format and yielded a fractional DoF similar to NMR in most cases. In comparing with NMR, we identified that DoF can be expressed as fractional or absolute, and that fractional DoF can be inaccurate if the amino acid content of the parent protein is not properly accounted for. In summary, the fractional DoF of methacryloyl- and norbornene-functionalized gelatins was quantified by an optimized colorimetric ninhydrin assay and orthogonally by 1 H NMR. These methods will be valuable for quality control analysis of protein-based hydrogels and 3D cell culture biomaterials. Graphical abstract
doi_str_mv 10.1007/s00216-020-02792-5
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An important and variable characteristic of these materials is the degree of functionalization (DoF), which controls the reactivity of the protein for cross-linking and therefore impacts the mechanical properties and stability of the hydrogel. Although 1 H NMR has emerged as the most accurate technique for quantifying absolute DoF of chemically modified proteins, colorimetric techniques still dominate in actual use and may be more useful for quantifying fractional or percent DoF. In this work, we sought to develop an optimized colorimetric assay for DoF of common gelatin-based biomaterials and validate it versus NMR; along the way, we developed a set of best practices for both methods and considerations for their most appropriate use. First, the amine-reactive ninhydrin assay was optimized in terms of solvent properties, temperature, ninhydrin concentration, and range of gelatin standards. 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subjects Amino acids
Analytical Chemistry
Assaying
Biochemistry
Biomaterials
Biomedical materials
Cell culture
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Colorimetry
Crosslinking
Female Role Models in Analytical Chemistry
Food Science
Gelatin
Hydrogels
Laboratory Medicine
Mechanical properties
Monitoring/Environmental Analysis
Ninhydrin
NMR
Nuclear magnetic resonance
Paper in Forefront
Proteins
Quality control
title Quantification of fractional and absolute functionalization of gelatin hydrogels by optimized ninhydrin assay and 1H NMR
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