Journal of the Korean Society of Food Science and Nutrition (한국식품영양과학회지)

The Korean Society of Food Science and Nutrition (한국식품영양과학회)
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Development of Low-fat Meat Processing Technology using Interaction between Meat Proteins and Hydrocolloids-II Development of Low-fat Sausages Using the Results of Model Study

식육단백질과 친수성 콜로이드의 상호결합 특성을 이용한 저지방 육제품 제조기술 개발 - II 모델연구결과를 이용한 저지방 소시지의 개발

  • Chin, Koo-Bok (Dept. of Animal Science and Institute of Agricultural Science and Technology, Chonnam National University) ;
  • Lee, Hong-Chul (Dept. of Animal Science and Institute of Agricultural Science and Technology, Chonnam National University)
  • 진구복 (전남대학교 동물자원학부 및 농업과학 기술연구소) ;
  • 이홍철 (전남대학교 동물자원학부 및 농업과학 기술연구소)
  • Published : 2002.08.01
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Abstract

This study was performed to develop low-fat comminuted sausages (LFSs, < 3%) manufactured with 1% single (Konjac flour, KF; kappa-carrageenan, k-CN and Locust bean gum, LBG) or mixed hydrocolloids and to select the best combination which had similar textural characteristics to those with regular-fat (~25% fat) control. In experiment 1, LFSs were formulated with each 1% hydrocolloid, smoked and cooked to an internal temperature of 71.7$^{\circ}C$. The pH range of LFSs was 6.29 to 6.34 and approximately 23~24% of fat was removed in the final products, resulting in the higher moisture and protein contents (%) in LFSs, as compared to regular-fat control. No differences (p>0.05) in cooking loss (CL, %), expressible moisture (EM, %), and hunter color values (L, a, b) were observed with the addition of each 1% hydrocolloid. However, LFSs containing 1% k-CN had textural hardness values similar to those with low-/regular-fat controls, whereas LFSs having either KF or LBG had similar cohesiveness values to those with regular-fat counterpart. Tn experiment 2, two or three mixed hydrocolloids were added to the low-fat sausage formulation. The addition of mixed KF+LBG (KLL) and KF+CN+LBG(KCL) reduced EM and textural hardness values, as compared to low-fat control. Among the treatments, LFSs containing two or three combinations of CN with KF or/and LBG had similar textural characteristics to those with regular-fat control. These results suggested that multiple addition of CN with other hydrocolloids (KF or LBG) for the replacement of fats in LFSs would be recommended for the proper functional and textural properties.

본 연구는 유화형 소시지와 유사한 물성을 갖는 저지방 소시지를 제조하기 위하여 실시하였다. 이전의 모델연구결과를 통해 얻은 최적조건을 저지방 육제품 제조에 적용하였으며 제조한 저지방 소시지의 pH는 6.29~6.34, 수분 74~76%, 지방<3% 및 단백질 15~18%인 반면, 유화형 소시지는 pH 6.51, 수분 56%, 지방 26.9% 및 단백질은 13.2%이었다. 친수성 콜로이드를 단독으로 첨가한 저지방 처리구는 무침가구와 비교할 때 가열수율, 보수력 및 색도에 영 향을 미치지 않았으나, CN을 첨가한 처리구의 보수력은 유화형 대조구와 KF 및 LBG를 각각 단독으로 첨가한 처리구에 비하여 오히려 낮았다. 물성특성에서는 저지 방 대조구와 CN을 첨가한 저지방 처리구가 유화형대조구보다 탄력성 및 응집성이 높았고, KF와 LBG를 각각 첨가한 처리구는 부서짐성과 경도 및 탄력성이 낮았다. KF, CN 및 LBG의 2종 내지 3종을 복합으로 첨가하여 저지방 소시지를 제조하였을 때 유화형 대조구에 비하여는 보수력은 떨어졌으나, KF와 LBG(KLL) 및 KF와 CN과 LBG(KCL)를 복합으로 첨가한 처리구는 단독 첨가구에 비하여 보수력이 증진되었다. 물성적인 특성에 있어서는KF와 LBG를 혼합하여 첨가한 처리구를 제외하고 다른 혼합 첨가구는 유화형 대조구와 비교적 유사한 물성적인 성상을 가졌으며 그 중 KF와 CN의 복합처리구가 유화형 대조구와 가장 유사한 물성을 가졌다. 이상의 결과에서 볼 때 기존의 유화형 대조구와 유사한 물성을 갖는 저지방 소시지를 개발하기 위하여 친수성 콜로이드의 단일첨가보다는 보수력이 좋은 KF 혹은 LBG등과 경도를 높여 주는 CN과의 복합지방대체제의 첨가가 더욱 효율적임을 알 수 있었다.

Keywords

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