Hydrodynamic Shock Wave Effects on Protein Functionality

Schilling, Mark Wesley

23 September 1999

USDA Select bovine Biceps femoris (BF) samples were divided into four sections and randomly assigned to three hydrodynamic shock wave (HSW) treatments and a control. Different amounts of explosive (105 g, H1; 200 g, H2; 305 g, H3) were suspended in the center of the hemishell tank, 26.7 cm above the vacuum packaged beef placed on the bottom center of that water-filled tank and detonated, representing three HSW treatments. In addition, BF steaks (2.54-cm thick) from a different and limited common source (2 muscles) were packaged with each HSW designated BF section. These served as internal refernce steaks (IRS) for the six replications to determine if the HSW treatments physically altered the structural integrity of the meat. H1 and H3 decreased (P<0.05) Warner-Bratzler shear values of the IRS from 3.86 and 3.99 kg (controls) to 3.01 and 3.02 kg (HSW), respectively. H2 shear values, 3.86 (control) to 3.46 kg (HSW) were not different (P> 0.05). HSW and control BF sections were analyzed for protein solubility and then used to manufacture frankfurters formulated with 2.0% NaCl, 0.5 % sodium tripolyphosphate, 156 ppm sodium nitrite, 0.42 % sodium erythorbate, 2.0 % sucrose, and 25 % water. Frankfurters (cooked to 71 C) were evaluated for cooking yield, CIE L*a*b*, nitrosylhemochrome, Texture Profile Analysis (hardness, cohesiveness), and stress and strain (torsion testing). Compared to the control samples, the HSW did not affect (P>0.05) myofibrillar or sarcoplasmic protein solubility, cooking yield, or color. Textural properties and gel strength of the frankfurters were not affected (P>0.05) by the HSW. These results indicate that beef trim obtained from HSW processed meat can be used interchangeably with normal meat trim in the production of further processed meats since the functionality of meat protein is not affected significantly by the HSW process. / Master of Science

tenderness

protein functionality

frankfurters

hydrodynamic shock waves

Investigations on the Great Northern Beans (Phaseolus Vulgaris L.): Protein Functionality, Antinutrients, Flatus Factors, Fermentation, and Carbohydrates

Sathe, Shridhar K.

01 May 1981

Protein content of the Great Northern beans was 26.10 percent on a dry weight basis. The apparent isoelectric pH of the NaCl extractable proteins was about 4.4. Among the several solubilizing agents, Na2CO3, K2S04, sodium dodecyl sulfate (SDS), and NaOH at the respective concentrations of 0.5, 5.0, 5.0 (all w/v), and 0.02 N were the best protein solubilizing agents, solubilizing 93.6 grams Lowry protein per 100 grams Kjeldahl protein. AIbumins and globulins accounted for 21.18 and 73.40 percent, respectively, of the total bean proteins. The bean proteins were fractionated and protein concentrates and protein isolates were prepared. The bean flour proteins, albumins, globulins, protein concentrates, and protein isolates (heretofore referred to as fractions) were studied electrophoretically. Several functional properties of the fractions were investigated. Protein concentrates had the highest water and oil absorption capacity (5.93 and 4.12 g/g, respectively) and emulsion capacity (72.6 g oil emulsified/g). Albumins registered the highest emulsion stability (780 hours at 21 °C). Foaming performance of the Great Northern bean proteins was fair and concentration dependent. Sorption isotherms studies indicated that the bean flour had higher equilibrium moisture content at corresponding temperature and equilibrium relative humidity than other fractions. Buffer capacity of the bean proteins over a pH range of 4-8 was modest. Modification (succinylation and oxidation) improved the water and oil absorption capacity of the bean proteins. Globulins registered the highest stickiness (92 N) among all the fractions. Alkali solubilization of the bean proteins resulted in significant reduction in trypsin and chymotrypsin inhibitory activities and elimination of hemagglutinating activity. Protein concentrates were essentially void of flatulence activity. Amino acid profiles indicated that the bean flour proteins, albumins, and protein isolates contained high acidic amino acids, while globulins and protein concentrates were characterized by high proportions of hydrophobic amino acids. Sulfur containing amino acids and leucine were the first and second limiting amino acids in the Great Northern bean proteins. Heat treatment of the fractions improved the in vitro protein digestibility. Baking studies indicated that replacement of wheat flour by the bean flour and the protein concentrates for improved nutritionality of cookies and bread was possible without adversely affecting the sensory quality attributes. In cookie preparation, bean flour and protein concentrates could replace wheat flour up to 30 percent and 20 percent (by weight), respectively; the corresponding figures for the wheat flour replacement in breadmaking were 10 percent and 10 percent (by weight). Fermentation of the Great Northern beanrice blends suggested the potential for these beans in developing fermented foods. The beans contained 59.20 percent (on a dry weight basis) of starch. Starch granule size ranged from 12 X 12 μm to 58 X 40 μm (length X width) and the granule shape was round to oval to elliptical, and in certain cases, concave as well. Lamellae were present on all the starch granules observed. Amylose content of the starch was 10.20 percent (on starch basis). Stable gel formation by the bean starch was observed at concentrations of 7 percent and above (w /v). The viscoamylographic studies of the isolated starch indicated the restricted swelling character of the bean starch. Solubility and swelling of the bean starch was both pH and temperature dependent. The addition of free fatty acids to the isolated starch reduced the viscosity and raised the gelatinization temperature of the bean starch. Modifications (acetylation and oxidation) of the isolated starch resulted in altered solubility and swelling characteristics. Replacement of wheat flour by the bean starch caused an increase in alkaline water retention capacity. The bean contained an arabinogalactan type mucilage principle (arabinose:galactose ratio of 2.0: l.7), the viscosity of which was dependent on concentration, pH, and temperature.

Great northern beans

protein functionality

antinutrients

fermentation

flatus factors

Food Science

Reduction of Fat Content in Processed Meats Using Hot-Boning and Cold-Batter Mincing Technology

Wonderly, Morgan P

01 June 2020

Processed meats have received negative publicity due to high fat contents that have been linked to adverse effects on human health. Fat is an essential ingredient in many processed meat products, so reducing this all while maintaining the desired characteristics of the product is a challenge. The purpose of this study was to generate low-fat meat products using a combination of hot-boning/crust-freeze-air-chilling (HB-CFAC) and cold-batter mincing (CBM) technologies. Pork hams were subjected to HB-CFAC or chill-boning/crust-freeze-air-chilling (CB-CFAC) prior to 3 min pre-mincing and 6 min mincing for control gels with back-fat addition or low-fat gels with water addition instead of the reduced back-fat. Raw meat quality, protein functionality and textural properties were analyzed through various analyses. The pH values of HB muscle and cooked gels were significantly higher than those of CB muscle and cooked gels. The fat and moisture contents of control gels was higher and lower, respectively, than those of low-fat gels, regardless of HB or CB. The protein functionality and gel forming ability of HB muscle were superior to those of the CB muscle, regardless of fat content. These results indicate that fat can be reduced with no loss of textural quality because cold-batter mincing of the HB-CFAC muscle resulted in higher gel forming ability than that of CB-CFAC muscle.

Hot-Boning

Crust-Freezing

Cold-Mincing

Low-Fat

Protein Functionality

Meat Science