Fat Reduction in Processed Meat Using Hot-Boning and Cold-Batter Mincing Technology
- Morgan P. Wonderly (California Polytechnic State University)
- Hong C. Lee (California Polytechnic State University)
- Siroj Pokharel (California Polytechnic State University)
- Gale M. Strasburg (Michigan State University)
- Bradley P. Marks (Michigan State University)
- Ike Kang (California Polytechnic State University)
Abstract
ObjectivesProcessed meats have high fat contents that have been linked to adverse effects on human health. The purpose of this study was to generate low-fat meat products using the combination of hot-boning (HB), crust-freeze-air-chilling (CFAC; HB-CFAC), and cold-batter mincing technologies.Materials and MethodsTwelve commercial pigs (4 pigs/replication) were obtained locally and processed in a traditional way. Skinless, boneless, fresh pork ham (IMPS#402G) was harvested and subjected to either hot-boning (HB) at 1-h poste-mortem or chill-boning (CB) at 24 h post-mortem. All pork ham muscles were cut into one-inch wide strips and subjected to crust-freeze-air-chilling (CFAC). The resulting strips were 3-min pre-chopped and 6-min post-chopped for full-fat batters (FF), using 65% ham muscle of CFAC, 15% pork back-fat, 16% ice, 2% salt, and 2% starch. For low-fat batters (LF), the strips were similarly chopped with the same ingredients except 0% pork back-fat and 31% ice. Data in three replications were evaluated by one-way ANOVA, using PASW 18 statistic program and a completely randomized design. A post-hoc analysis was performed using Duncan`s multiple range test to evaluate differences of fat content and protein functionality among treatments at P < 0.05.ResultsAfter chilling, the pH 6.27 of HB-loin muscles at an hour post-mortem was significantly higher than that pH 5.63 of CB-loin muscles at 24 h post-mortem (P < 0.05). Similarly, the pH 6.0 of cooked HB-gels was higher than the pH 5.7 of cooked CB-gels, regardless of fat content (P < 0.05). The 65% moisture and 11– 12% fat in full-fat gels (HB-FF and CB-FF) were lower and higher, respectively, than 76– 78% moisture and 1.6– 3.0% fat in low-fat gels (HB-LF and CB-LF), regardless of boning type. Cooking yield (%) was improved in HB-gels more than CB-gels. In responding to the cooking yield, the lowest and the highest expressible moistures were found in HB-FF gels and CB-LF gels, respectively. Both HB-FF and HB-LF gels showed higher values for hardness, cohesiveness, and gumminess than CB-FF gels, with the least value found in CB-LF gels. These results indicated that the cold-batter mincing of HB-muscles provided higher protein functionality and gel-forming ability than that of CB-muscles so that fat was reduced without textural quality loss (P < 0.05). The next step of this research is to generate fatty/creamy-like texture by chopping low-fat ham muscles at sub-zero temperatures for extended times, resulting in small and uniform protein particle sizes.
Keywords: hot-boning, protein functionality, cold mincing, low fat, crust-freeze-air-chilling
How to Cite:
Wonderly, M. P., Lee, H. C., Pokharel, S., Strasburg, G. M., Marks, B. P. & Kang, I., (2019) “Fat Reduction in Processed Meat Using Hot-Boning and Cold-Batter Mincing Technology”, Meat and Muscle Biology 3(2). doi: https://doi.org/10.22175/mmb.10796
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