Development of flavour in potato crisps and related model systems

Martin, Fiona L.

January 2001

No description available.

664

Maillard

Development of polymer-supported synthetic procedure for Heyns rearrangement products

Tateyama, Miho.

January 1999

Amadori and Heyns rearrangement products are currently produced as crude Maillard reaction mixtures, due to lack of convenient procedures for their synthesis. The objective of this study was to develop a synthetic strategy based on polymer-supported synthesis that allows the production of different derivatives of these sugar-amino acid conjugates. The strategy involved coupling of poly(ethyleneglycol) mono methyl ether (PEGME) with N-protected (t-BOC) amino acid through catalysis by DCC (dicyclohexylcarbodimide) to form a polymer bound ester of the amino acid (89% yield with beta-alanine), followed by deprotection of the t-BOC group through a novel microwave-assisted hydrolysis process in high yields (98%). After the deprotection, the polymer-based amino acid was neutralized by triethyl amine treatment, followed by room temperature reaction with selected reducing sugars or sugar analogs, for 48 hrs to produce polymer bound ARP in 75% yield (using acetol). The final product was cleaved by methanolysis using sodium methioxide in 65% yield. The reactions were monitored by spectroscopic analysis and the intermediates were identified by FTIR, Py/GC/MS and 1H NMR.

Maillard reaction.

Isolation and identification of non-volatile water soluble Maillard reaction products

Kaminski, Eva.

January 1997

A water-methanol solution of glycine and scD-glucose was refluxed for seven hr. The solvent was evaporated under vacuum at room temperature and the residue was dialyzed against distilled water. After dialysis, the solvent was evaporated under vacuum at room temperature. The non-dialyzable fraction was further fractionated by gel filtration. The process yielded three polymeric materials (10,000 $<$ M $<$ 20,000) whose purity was verified by HPLC. The isolated polymers were further analyzed by UV-VIS and FTIR spectroscopy and by pyrolysis/GC/MS. Elemental analysis indicated that polymer A has the following empirical formula $ rm C sb6H sb{11}N sb1O sb4$ and polymers B1 and B2 have the same empirical formula as glucose $ rm C sb1H sb2O sb1.$ The origin of nitrogen containing polymer A was assigned to Amadori intermediate or to some of its derivatives and the origin of polymers B1 and B2 was assigned to Glucosone and to 3- or 1-deoxyglucosones; common non-nitrogen containing reactive intermediates during Maillard reaction. Plausible mechanisms were proposed for the formation of polymers.

Maillard reaction.

Development of polymer-supported synthetic procedure for Heyns rearrangement products

Tateyama, Miho.

January 1999

No description available.

Maillard reaction.

Isolation and identification of non-volatile water soluble Maillard reaction products

Kaminski, Eva.

January 1997

No description available.

Maillard reaction.

Glycation of basic fibroblast growth factor : relevance to diabetic wound healing

Duraisamy, Yasotha

January 2001

No description available.

572

Diabetes; Maillard

Novel techniques in combinatorial chemistry and their applications

Kuhn, Claudia

January 2002

No description available.

664

Maillard products

Applications of Py-GCMS to the study of maillard reaction : mechanistic and food quality aspects

Wnorowski, Andrzej

January 2003

No description available.

Maillard reaction.

Pyrolysis.

Phloretin and phloridzin as modulators in maillard reaction model systems

Ma, Jinyu, 马金余

January 2011

published_or_final_version / Biological Sciences / Doctoral / Doctor of Philosophy

Flavonoids.

Maillard reaction.

PYGCMS investigation of the mechanism of Maillard reaction using isotopically enriched amino-acids and d-glucoses

Keyhani, Anahita.

January 1997

Pyrolysis/GC/MS was utilized as an integrated reaction, separation and identification system to study the thermal degradation products of non-volatile Maillard flavor precursors. Model systems of scL-phenylalanine (aromatic amino acid), glycine and scL-alanine (aliphatic amino acids), scL-serine ($ beta$-hydroxy amino acids) and scL-methionine (sulphur containing amino acid) were investigated. Quartz tube pyrolysis of scD-glucose/amino acid or dicarbonyl/amino acid mixtures shortened the analysis time (from hours to minutes) and eliminated the need for extraction since the volatiles generated from the precursors are directly transferred into the GC column. / Phenylalanine Amadori product and different model systems containing phenylalanine and different reducing sugars were studied. Ribbon pyrolysis was used to study the effect of temperature (150, 200, 250$ sp circ$C) on the efficiency of formation of initial pyrolysis products from phenylalanine and Amadori phenylalanine. Quartz tube pyrolysis was used at 250$ sp circ$C to enhance the secondary reactions. These studies revealed the formation of pyridine and naphthalene derivatives such as 3,5-diphenylpyridine, 1(2)-naphthaleneamine, N-methyl-1(2)-aminonaphthalene, 1-aminoanthracene, 2$ sp prime$-phenyl-pyrrolo (4,5-A) dihydronaphthalene, 1(2)-(N-phenethyl)napthaleneamine and 1(2)-(N-phenethyl-N-methyl)naphthaleneamine. / Model studies using scD- ($ sp{13}$C) glucoses and a series of dicarbonyl compounds with labeled ($ sp{15}$N/$ sp{13}$C) glycines and ($ sp{15}$N/$ sp{13}$C) alanines identified a new chemical transformation of $ alpha$-dicarbonyls, that lead to the addition of alkyl groups from the amino acid to the $ alpha$-dicarbonyl compounds, instead of the amino group as in the case of the Strecker type interaction between the two reactants. Thus, glyoxal and pyruvaldehyde can be transformed into pyruvaldehyde and 2,3-butanedione respectively, by glycine and 2-ketobutanal and 2,3-pentanedione respectively, by scL-alanine. The labeled glycine model studies indicated that methyl substituted pyrazines and pyrazinones formed in the model systems, have a common intermediate. Two pathways of pyrazinone formation were distinguished based on the labeling experiments, one involving the reaction of three moles of glycine and the other the interaction of the dipeptide glycylglycine with an $ alpha$-dicarbonyl compound. / A major product of the reaction of scD-glucose with excess glycine was detected by Py/GC/MS analysis and subsequently synthesized and isolated using focused microwave irradiation at atmospheric pressure conditions. Spectroscopic analysis by NMR, FTIR, MS and UV in conjunction with labeling studies have indicated the unknown compound to be 5-hydroxy-1,3-dimethyl-2 (1H) -quinoxalinone. The labeling studies indicated the incorporation of ten carbon atoms (six from sugar, one C-1 atom of glycine, and three C-2 atoms of glycine) and two nitrogens. / scL-Serine was found to be a unique amino acid generating in the absence of sugar a variety of heterocyclic compounds. Under pyrolytic conditions scL-serine can be viewed as a potential mixture of glycine, alanine, serine, formaldehyde and dicarbonyl compounds. / Model studies with scL-methionine provided evidence that methional (Strecker aldehyde) generated under Quartz tube pyrolysis undergoes secondary reactions with amino compounds generating 1,3-thiazines or 3-substituted pyridine in a similar fashion to that of scL-phenylalanine systems where 3-substituted pyridines were also identified. (Abstract shortened by UMI.)

Maillard reaction.

Pyrolysis.