Effect Of Exposing Calf's Muscle (Biceps Femoris) To A Hydraulic Pressure On Some of Intrinsic Histological And Physiological Traits

Authors

  • Nadia Abdul Hadee Abdul Ameer Al-Forat Al-Awsat Technical University 31003, Iraq
  • Shatha Atta Ubaid Al-Forat Al-Awsat Technical University 31003, Iraq
  • Mahmood Mezher Maahmood College of Agricultural Engineering Science, University of Baghdad

Keywords:

hydraulic pressure, muscle microstructure, WHC, shear force, FI, MFI, protein solubility, myoglobin concentrations, muscle histology

Abstract

Samples of Biceps Femoris muscle of Iraqi calves has been exposed to a hydraulic pressure and measuring some of physiological and histological changes. The experiment divided to five treatments, TRT cont. with no hydraulic pressure applied (0 bar), TRT2 with 50 bar, TRT3 with 100 bar, TRT4 with 200 bar and TRT5 with 300 bar hydraulic pressure applied. The studied physiological properties were (water holding capacity WHC, shear force SF, fragmentation index FI, myofibril fragmentation index MFI, protein solubility and myoglobin concentrations Mg. some sample from each treatment were tested microscopically under magnification of 600, 1000 and 1600X to find out the changes in muscle microstructure. All treatments had an obvious effect on muscle samples and the differences between means were significant (p˂0.05). the histological profile of muscle differed significantly from each treatment to other with the increasing of applied pressure. At first (TRT2 50 bar) the muscle tissue structure had a slight deviation from TRT cont. while at the last treatment TRT5 (300 bar) the muscle microstructure torn up completely and the physiological tissue system had extremely disappeared.

References

Mkrtehyan M., Safronov D., Tokarev A., Makavchik S. and Orlova D. 2020. Determination the quality of meat, manufactured meat, and meat products via the histological method. International Transaction Journal of Engineering Management, and Applied Science and Technologies. V11, Paper ID: 11A15J.

Kaimbayeva L., Kenenbay S., Dikhanbaeva F., Tnymbaeva B. and Kazihanova S. 2021. Histological studies of muscle tissue of the Bactrian camel meat in the process of autolysis. Food Science and Technology. 41(2): 371-375.

Listrat A., Lebret B., Louveau I., Astruc T., Bonnet M., Lefaucheur L., Picard B. and Bugeon J. 2016. How Muscle Structure and Composition Influence Meat and Flesh Quality. Scientific World Journal Volume 2016, Article ID 3182746, 14 pages http://dx.doi.org/10.1155/2016/3182746.

Anderson, M. J., Lonergan, S. M., Fedler, C. A., Prusa, K. J., Binning, J. M., & Huff-Lonergan, E. (2012). Profile of biochemical traits influencing tenderness of muscles from the beef round. Meat science, 91(3), 247-254..

Xing, T., Gao, F., Tume, R. K., Zhou, G., & Xu, X. (2019). Stress effects on meat quality: a mechanistic perspective. Comprehensive Reviews in Food Science and Food Safety, 18(2), 380-401.

Channon, H. A., D’Souza, D. N., & Dunshe, F. R. 2016. Flavour and juiciness of pork using Monte Carlo simulation methods. Meat Science, 116, 58–66.

Bhat, Z. F., Morton, J. D., Mason, S., & Bekhit, A. E. D. (2018). Current and future prospects for the use of pulsed electric field in the meat industry. Critical Reviews in Food Science and Nutrition, 1–5. https://doi.org/10.1080/ 10408398.2018.1425825

Irurueta, M., Cadoppi, A., Langman, L., Grigioni, G., & Carduza, F. (2008). Effect of aging on the characteristics of meat from water buffalo grown in the Delta del Parana region of Argentina. ´ Meat Science, 79, 529–533.

Kim, H. W., Choi, Y. S., Choi, J. H., Kim, H. Y., Lee, M. A., Hwang, K. E., Kim, C. J. (2013). Tenderization effect of soy sauce on beef M. biceps femoris. Food Chemistry, 139, 597–603.

Sullivan, G. A., & Calkins, C. R. (2010). Application of exogenous enzymes to beef muscle of high and low-connective tissue. Meat Science, 85, 730–734.

Sikes, A. L., Mawson, R., Stark, J., & Warner, R. (2014). Quality properties of pre- and post-rigor beef muscle after interventions with high frequency ultrasound. Ultrasonics Sonochemistry, 21, 2138–2143.

Mcardle, R. A., Marcos, B., Mullen, A. M., & Kerry, J. P. (2013). Influence of HPP conditions on selected lamb quality attributes and their stability during chilled storage. Innovative Food Science and Emerging Technologies, 19, 66–72.

Dolatowski, J.Z. and Stasiak, D.M. (1998). The effect of low and intensity ultrasound on pre-rigor meat on structure and functional parameters of freezing and thawed beef semimebranosus muscle. Proc. 44th Int. Cong. Meat. Sci. Technol. Barcelona, Spain.

Omar, N. S., & Ali, R. T. (2019). Dosimetric Analysis with Intensity-modulated Radiation Therapy for Central Nervous System Irradiation in Patients with Brain Cancer Compared with Three-dimensional Conformal Radiation Therapy Treatment. Polytechnic Journal, 9(2), 9.‏.

Davis, G.W., Duston, T.R., Smith, G.C. and Carpenter, Z.L. (1980). Fragmentation procedure for bovine longissimus muscle as an index of cooked steak tenderness. J. Food. Sci. 45:880-884.

Culler, R.D., Parrish, F.C., Smith, G.C. and Cross, H.R. (1978). Relationship of myofibril fragmentation index to certain chemical, physical and sensory characteristics of bovine longissimus muscle. J. Food. Sci. 43:1177-1180.

Denhertog- Meischke, M.J.A., Smulderes, F.J.M., Vanloglestijn, and Vanknapen,F. (1997). The effects of electrical stimulation on the water holding capacity and protein denaturation of two bovine muscle. J. Anim. Sci. 75:118-124.

Gomall, A. G. , Bardawill , C. L. and David , M. M. (1949). Determination of serum protein by means of the biuret reaction . J. Biol. chem. 177 : 751-753.

Zessin D., Pohu C., Wilson G. and Carrigan D. 1961. Effect of pre-slaughter dietary stress on the carcass characteristics and palatability of pork. Journal of Animal Science. 20: 871-876.

Woods, J.; and Ellis, M. (1994). Laboratory Histopathology: A complete Reference. Churchill Livingstone.

Tornberg, E. (2005). Effects of heat on meat protein: implications on structure and quality of meat products. Meat Science. 70:493-508.

Bertram, H.C., Purslow, P.P. and Anderson, H.J. (2002). Relationship between meat structure, water mobility, and distribution: A low-field Nuclear magnetic resonance study. J. Agri. Food Chem. 50:824-829.

Swatland, H.J. (1989). Objective measurement of physical aspects of meat quality. Proc. 42nd Annual Recip. Meat Conference. PP.65-74.

Lyon, C.E., and Lyon, B.G. (1991). The relationship of objective shear values and sensory tests to changes in tenderness of broiler breast meat. Poultry Sci. 69:1420-1427.

Davis, G.W., Duston, T.R., Smith, G.C. and Carpenter, Z.L. (1980). Fragmentation procedure for bovine longissimus muscle as an index of cooked steak tenderness. J. Food. Sci. 45:880-884.

Cable, J.R.,(1983). fragmentation index as an early postmortem predictor of beef tenderness. MSc. Thesis. Texas Tech. Univ.

Bates, P.C. and Millward, D.J. (1983). Myofibril protein turnover: synthesis rate of myofibrillar and sarcoplasmic protein fractions in different muscles and the changes observed during postnatal development and in response to feeding and starvation. Biochem. J. 214:587-592.

Veiseth, E., Shackelford, S.D., Wheeler, T.L. and Koohmaraie, M. (2001). Technical note: comparison of myofibril fragmentation index from fresh and frozen pork and lamb longissimus. J. Anim. Sci. 79:904- 906.

Veiseth, E., Shackelford, S., Wheeler, T., & Koohmaraie, M. (2004). Factors regulating lamb longissimus tenderness are affected by age at slaughter. Meat Science, 68, 635–640.

Koohmaraie, M. (1992). Ovine skeletal muscle multicatalytic proteinase complex (proteosome) purification , characterization and comparison of its effects on myofibrils with μ-calpin. J. Anim. Sci. 70:3697-3708.

Wheeler, T. L., Koohmaraie, M., Lansdell, J. L., Siragusa, G. R., & Miller, M. F. (1993). Effect of postmortem injection time, injection level, and concentration of calcium chloride on beef quality traits. Journal of Animal Science, 71, 2965–2974.

Omar, N. S., Ahmed, F. K., Saleem, D. S., Shah, L. J. A., & Abbas, M. A. (2024). Influence of Maternal Body Mass Index on Fetal Ultrasound Biometry. Cihan University-Erbil Scientific Journal, 8(2), 93-98.

Lowe D., Warren G., Snow L., Thompson L. and Thomas D. 2004. Muscle activity and aging affect myosin structure distribution and force generation in rat fibers. Journal of Application Physiology. 96: 498-509.

Young O. and West J. 2001. Meat color. MIRTZ Centre. Agricultural researche, Hamilton, New Zealand. Marcel Dekker, Inc. Press.

Kerr M., Warner R. and Natharampatha A. 2010. Muscle haem content and color are affected by age category and muscle type, but not by exsanguinations method in sheep meat, Proc. Aust. Soc. Animal Prod. 28:114/

Lestyk K., Folkow L. Blix A., Hammill M. and Burns J. 2009. Development of myoglobin concentration and acid buffering capacity in harp (Pagophilus groenlandicus) and hooded (cystophora cristata) seals from birth to maturity. Journal Comp. Physiology. 179:985-996.

Migaldi M., Rossi G., Sgmabato A., Farinetti A. and Mattioli A. 2016. Histological and immunohistochemical analysis of meat-based food preperations. Progress in Nutrition. 18:276-282.

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Published

2025-03-14

How to Cite

Abdul Hadee Abdul Ameer, N., Atta Ubaid, S., & Mezher Maahmood, M. (2025). Effect Of Exposing Calf’s Muscle (Biceps Femoris) To A Hydraulic Pressure On Some of Intrinsic Histological And Physiological Traits. Scholastic: Journal of Natural and Medical Education, 4(1), 1–12. Retrieved from https://journal.univerpublishing.org/index.php/scholastic/article/view/3282

Issue

Vol. 4 No. 1 (2025): January

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Articles