Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats

Jamila Smanalieva; Zhyldyzai Ozbekova; Asylbek Kulmyrzaev; Peter Fischer

TR EN

Investigation of Fatty Acid Composition, Thermal and Rheological Behavior of Yak, Cow and Horse Fats

Abstract

The objective of this paper was to study the fatty acid composition, and thermal and rheological behavior of Kyrgyz yak (Bos grunniens) visceral fats compared to visceral fats of cow (Bos taurus) and horse (Equus caballus). The result of the studу revealed that the content of saturated fatty acids (SFA) in yak fat was higher than those of unsaturated fatty acids (UFA) (about 58.3 and 38.0 %, respectively). The UFA content in yak fat was higher compared to cow fat (about 27.1 %) and lower than that of horse fat (about 60.0 %). The melting temperatures determined using DSC were found to be 55.18±0.71, 54.98±3.01, 37.60±1.92 °C for yak, cow and horse fat, respectively. These results were close to the solid-liquid transition temperature determined by oscillation rheology (52.20±0.89 °C for yak, 53.56±3.53 °C for cow and 33.7±1.84 °C for horse fat). Rotational rheological measurements at 35 °C have shown that yak fat had shear thinning flow behavior with high a viscosity of 226 mPas compared to horse fat, which has Newtonian flow behavior with a viscosity of about 36 mPas (γ=100s^-1). Results on properties obtained in this study will help to understand the contribution of yak fats to the structural properties of new products with these alternative fat sources.

Keywords

Yak fat, fatty acids, rheology, flow behavior, melting

Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats

Abstract

The objective of this paper was to study the fatty acid composition, and thermal and rheological behavior of Kyrgyz yak (Bos grunniens) visceral fats compared to visceral fats of cow (Bos taurus) and horse (Equus caballus). The result of the studу revealed that the content of saturated fatty acids (SFA) in yak fat was higher than those of unsaturated fatty acids (UFA) (about 58.3 and 38.0 %, respectively). The UFA content in yak fat was higher compared to cow fat (about 27.1 %) and lower than that of horse fat (about 60.0 %). The melting temperatures determined using DSC were found to be 55.18±0.71, 54.98±3.01, 37.60±1.92 °C for yak, cow and horse fat, respectively. These results were close to the solid-liquid transition temperature determined by oscillation rheology (52.20±0.89 °C for yak, 53.56±3.53 °C for cow and 33.7±1.84 °C for horse fat). Rotational rheological measurements at 35 °C have shown that yak fat had shear thinning flow behavior with high a viscosity of 226 mPas compared to horse fat, which has Newtonian flow behavior with a viscosity of about 36 mPas (γ=100s^-1). Results on properties obtained in this study will help to understand the contribution of yak fats to the structural properties of new products with these alternative fat sources.

Keywords

Yak fat, fatty acids, rheology, flow behavior, melting

Supporting Institution

Kyrgyz-Turkish Manas University

References

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Details

Primary Language

English

Subjects

Engineering

Journal Section

Research Article

Authors

Jamila Smanalieva ^*
0000-0002-3929-4291
Kyrgyzstan

Zhyldyzai Ozbekova
0000-0002-2471-5006
Kyrgyzstan

Asylbek Kulmyrzaev This is me
0000-0003-3375-2818
Kyrgyzstan

Peter Fischer This is me
0000-0003-3242-9867
Swaziland

Publication Date

June 18, 2019

Submission Date

May 7, 2019

Acceptance Date

May 29, 2019

Published in Issue

Year 2019 Volume: 7 Number: 1

IZ

https://izlik.org/JA52XX22PD

APA

Smanalieva, J., Ozbekova, Z., Kulmyrzaev, A., & Fischer, P. (2019). Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats. MANAS Journal of Engineering, 7(1), 24-33. https://izlik.org/JA52XX22PD

AMA

1.Smanalieva J, Ozbekova Z, Kulmyrzaev A, Fischer P. Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats. MJEN. 2019;7(1):24-33. https://izlik.org/JA52XX22PD

Chicago

Smanalieva, Jamila, Zhyldyzai Ozbekova, Asylbek Kulmyrzaev, and Peter Fischer. 2019. “Investigation of Fatty Acid Composition, Thermal and Rheological Behavior of Yak, Cow and Horse Fats”. MANAS Journal of Engineering 7 (1): 24-33. https://izlik.org/JA52XX22PD.

EndNote

Smanalieva J, Ozbekova Z, Kulmyrzaev A, Fischer P (June 1, 2019) Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats. MANAS Journal of Engineering 7 1 24–33.

IEEE

[1]J. Smanalieva, Z. Ozbekova, A. Kulmyrzaev, and P. Fischer, “Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats”, MJEN, vol. 7, no. 1, pp. 24–33, June 2019, [Online]. Available: https://izlik.org/JA52XX22PD

ISNAD

Smanalieva, Jamila - Ozbekova, Zhyldyzai - Kulmyrzaev, Asylbek - Fischer, Peter. “Investigation of Fatty Acid Composition, Thermal and Rheological Behavior of Yak, Cow and Horse Fats”. MANAS Journal of Engineering 7/1 (June 1, 2019): 24-33. https://izlik.org/JA52XX22PD.

JAMA

1.Smanalieva J, Ozbekova Z, Kulmyrzaev A, Fischer P. Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats. MJEN. 2019;7:24–33.

MLA

Smanalieva, Jamila, et al. “Investigation of Fatty Acid Composition, Thermal and Rheological Behavior of Yak, Cow and Horse Fats”. MANAS Journal of Engineering, vol. 7, no. 1, June 2019, pp. 24-33, https://izlik.org/JA52XX22PD.

Vancouver

1.Jamila Smanalieva, Zhyldyzai Ozbekova, Asylbek Kulmyrzaev, Peter Fischer. Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats. MJEN [Internet]. 2019 Jun. 1;7(1):24-33. Available from: https://izlik.org/JA52XX22PD

Manas Journal of Engineering

16155

Investigation of Fatty Acid Composition, Thermal and Rheological Behavior of Yak, Cow and Horse Fats

Abstract

Keywords

Investigation of fatty acid composition, thermal and rheological behavior of yak, cow and horse fats

Abstract

Keywords

Supporting Institution

References

Details

Primary Language

Subjects

Journal Section

Authors

Publication Date

Submission Date

Acceptance Date

Published in Issue

IZ

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