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L. Landolt, H. Hultin (1981)
THE REMOVAL OF TRIMETHYLAMINE OXIDE AND SOLUBLE PROTEIN FROM INTACT RED HAKE MUSCLE BY WASHINGJournal of Food Processing and Preservation, 5
DYER DYER, HILTZ HILTZ (1974)
Sensitivity of hake muscle to frozen storageFish. Environ. Can., Fish. Mar. Serv., Technol. Stn., Halifax, New Ser. Circ., 45
C. Castell, Barbara Smith, W. Dyer (1973)
Effects of Formaldehyde on Salt Extractable Proteins of Gadoid MuscleWsq: Women's Studies Quarterly, 30
MURRAY MURRAY, GIBSON GIBSON (1972)
An investigation of the method of determining trimethylamine in fish muscle extracts by the formation of its picrate salt ‐ Part 1J. Food Technol., 7
M. Yamagata, K. Horimoto, Chujiro Nagaoka (1969)
Assessment of Green Tuna: Determining Trimethylamine Oxide and its Distribution in Tuna MusclesJournal of Food Science, 34
H. Dowden (1938)
The determination of small amounts of dimethylamine in biological fluids.The Biochemical journal, 32 3
T. Nash (1953)
The colorimetric estimation of formaldehyde by means of the Hantzsch reaction.The Biochemical journal, 55 3
T. Tokunaga (1974)
The effect of decomposed products of trimethylamine oxide on quality of frozen Alaska pollack filletNippon Suisan Gakkaishi, 40
TOKUNAGA TOKUNAGA (1974)
The effect of decomposition products of trimethylamine oxide on quality of frozen Alaska pollack filletBull. Jap. Soc. Sci. Fish., 40
W. Dyer, Yvonne Mounsey (1945)
Amines in Fish Muscle: II. Development of Trimethylamine and Other AminesWsq: Women's Studies Quarterly, 8
REGENSTEIN REGENSTEIN, HULTIN HULTIN, FEY FEY, KELLEHER KELLEHER (1980)
Utilization of red hakeMarine Fish. Rev., 42
J. Bystedt, L. Swenne, H. Aas (1959)
Determination of trimethylamine oxide in fish muscleJournal of the Science of Food and Agriculture, 10
C. Castell, W. Neal, J. Dale (1973)
Comparison of Changes in Trimethylamine, Dimethylamine, and Extractable Protein in Iced and Frozen Gadoid FilletsWsq: Women's Studies Quarterly, 30
K. Parkin, H. Hultin (1982)
SOME FACTORS INFLUENCING THE PRODUCTION OF DIMETHYLAMINE AND FORMALDEHYDE IN MINCED AND INTACT RED HAKE MUSCLEJournal of Food Processing and Preservation, 6
K. Parkin, H. Hultin (1982)
Fish muscle microsomes catalyze the conversion of trimethylamine oxide to dimethylamine and formaldehydeFEBS Letters, 139
J. Ferris, R. Gerwe, G. Gapski (1967)
Detoxication mechanisms. II. Iron-catalyzed dealkylation of trimethylamine oxideJournal of the American Chemical Society, 89
HARADA HARADA (1975)
Studies on enzymes forming formaldehyde and dimethylamine in fish and shellfishJ. Shimonoseki Univ. of Fish., 23
D. Crawford, D. Law, J. Babbitt, L. McGill (1979)
COMPARATIVE STABILITY AND DESIRABILITY OF FROZEN PACIFIC HAKE FILLET AND MINCED FLESH BLOCKSJournal of Food Science, 44
W. Dyer (1945)
Amines in Fish Muscle: I. Colorimetric Determination of Trimethylamine as the Picrate SaltWsq: Women's Studies Quarterly, 6
C. Castell, Barbara Smith (1973)
Measurement of Formaldehyde in Fish Muscle Using TCA Extraction and the Nash ReagentWsq: Women's Studies Quarterly, 30
ABSTRACT Previously indicated results that cofactor concentrations were the rate‐limiting factor in the production of DMA in frozen red hake muscle were confirmed. Both the Fe‐reducing agent (ascorbate, cysteine) and the flavin‐NADH systems which had been previously shown to be effective in vitro, were demonstrated to also function in minced muscle and in reconstituted muscle, i.e., muscle from which the low molecular weight fraction had been removed. The evidence implies that an oxidation‐reduction cycle of Fe is involved in the breakdown of TMAO to DMA. Activity with the flavin system is greatly increased in the presence of glucose oxidase and glucose which would remove O2 from the system. Fe was effective in increasing DMA production under all conditions, whereas Fe+3 was effective only in the presence of reducing agents and/or anaerobic conditions. Enzymes capable of destroying cofactors when added to minced muscle tissue before frozen storage inhibited the rate of formation of DMA. The percentage of formaldehyde produced which was bound (unreactive to the Nash reagent) was much higher in minced muscle than in reconstituted muscle, indicating that a large fraction of the formaldehyde produced reacts with the low molecular weight fraction.
Journal of Food Processing and Preservation – Wiley
Published: Dec 1, 1983
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