Molecular changes and interactions of wheat flour biopolymers during bread-making: Implications to upcycle bread waste into bioplastics.

This study aims to understand the molecular and supramolecular transformations of wheat endosperm biopolymers during bread-making, and their implications to fabricate self-standing films from stale white bread. A reduction in the Mw of amylopectin (51.8 × 106 vs 425.1 × 106 g/mol) and water extractable arabinoxylans WEAX (1.79 × 105 vs 7.63 × 105 g/mol), and a decrease in amylose length (245 vs 748 glucose units) was observed after bread-baking. The chain length distribution of amylopectin and the arabinose-to-xylose (A/X) ratio of WEAX remained unaffected during bread-making, suggesting that heat- or/and shear-induced chain scission is the mechanism responsible for molecular fragmentation. Bread-making also resulted in more insoluble cell wall residue, featured by water unextractable arabinoxylan of lower A/X and Mw, along with the formation of a gluten network. Flexible and transparent films with good light-blocking performance (<30 % transmittance) and DPPH-radical scavenging capacity (~8.5 %) were successfully developed from bread and flour. Bread films exhibited lower hygroscopicity, tensile strength (2.7 vs 8.5 MPa) and elastic modulus (67 vs 501 MPa) than flour films, while having a 6-fold higher elongation at break (10.0 vs 61.2 %). This study provides insights into the changes in wheat biopolymers during bread-making and sets a precedent for using stale bread as composite polymeric materials.

Simultaneous immunofluorescent imaging of gliadins, low molecular weight glutenins, and high molecular weight glutenins in wheat flour dough with antibody-quantum dot complexes.

Gluten proteins and their impact in the quality of wheat based food products is well known. In order visualize the 'in situ' distribution of low molecular weight glutenins, high molecular weight glutenins, and gliadins simultaneously in wheat doughs we needed to overcome and eliminate dough auto-fluorescence, and to develop a reliable immunostaining procedure for their simultaneous detection in wheat doughs. We are studying different auto-fluorescence quenchers used in biological fluorescent imaging and their effect on dough auto-fluorescence removal, and the effect of different fixative mediums on the adhesion of wheat flours doughs onto microscope slides. We found that the best method to remove dough auto-fluorescence is removing it as background in the microscope detection system. We also found methanol to be the best fixative medium for dough samples. In this research, we are showing the first 'in situ' localization of these gluten subunits simultaneously in wheat flour dough.

Conjugation of Specifically Developed Antibodies for High- and Low-Molecular-Weight Glutenins with Fluorescent Quantum Dots as a Tool for Their Detection in Wheat Flour Dough.

The importance of gluten proteins, gliadins and glutenins, is well-known in the quality of wheat products. To gain more specific information about the role of glutenins in wheat dough, the two major subunits of glutenin, high- and low-molecular-weight (HMW and LMW) glutenins, were extracted, isolated, and identified by mass spectrometry. Antibodies for HMW and LMW glutenins were developed using the proteomic information on the characterized glutenin subunits. The antibodies were found to be specific to each subunit by western immunoblots and were then conjugated to quantum dots (QDs) using site-click conjugation, a new method to keep antibody integrity. A fluorescence-link immunosorbent assay tested the successful QD conjugation. The QD-conjugated antibodies were applied to dough samples, where they recognized glutenin subunits and were visualized using a confocal laser scanning microscope.