Correlations between first order echotextural characteristics and chemical composition of pectoralis major muscles in broiler chickens receiving different dietary fat supplements

Ahmadi B., Mirshahi A., Giffin J., Oliveira M.E.F., Gao L., Hahnel A., Bartlewski P.M. (2013). Preliminary assessment of the quantitative relationships between testicular tissue composition and ultrasonographic image attributes in the ram. Vet. J., 198: 282–285.Search in Google Scholar

Anjum F.M., Haider M.F., Khan M.I., Sohaib M., Arshad M.S. (2013). Impact of extruded flaxseed meal supplemented diet on growth performance, oxidative stability and quality of broiler meat and meat products. Lipids Health Dis., 12: 13.Search in Google Scholar

Azain M.J. (2004). Role of fatty acids in adipocyte growth and development. J. Anim. Sci., 82: 916–924.Search in Google Scholar

Baracho M.S., Camargo G.A.I., Lima A.M.C., Mentem J.F., Moura D.J., Moreira J., Nääs I.A. (2006). Variables impacting poultry meat quality from production to pre-slaughter: a review. Braz. J. Poult. Sci., 8: 201–212.Search in Google Scholar

Blitz J. (1963). Fundamentals of Ultrasonics. Butterworth, London, U.K.Search in Google Scholar

Bodwell C.E., Anderson B.A. (1986). Nutritional composition and value of meat. In: Muscle as Food, Bechtel P.J. (ed.). Academic Press, New York, pp. 321–359.Search in Google Scholar

Bogucka J., Ribeiro D.M., Da Costa R.P.R., Bednarczyk M. (2018). Effect of synbiotic dietary supplementation on histological and histopathological parameters of pectoralis major muscle of broiler chickens. Czech J. Anim. Sci., 639: 263–271.Search in Google Scholar

Cady E.B., Gardener J.E., Edwards R.H.T. (1983). Ultrasonic tissue characterisation of skeletal muscle. Eur. J. Clin. Investig., 13: 469–473.Search in Google Scholar

Chanamai R., McClements D.J. (1999). Ultrasonic determination of chicken composition. J. Agric. Food Chem., 47: 4686–4692.Search in Google Scholar

Clague J.E., Roberts N., Gibson H., Edwards R.H. (1995). Muscle imaging in health and disease. Neuromuscul. Disord., 5: 171–178.Search in Google Scholar

Cobos Á., Díaz O. (2014). Chemical composition of meat and meat products. In: Handbook of Food Chemistry, P. Cheung (ed.). Springer, Berlin, Heidelberg.Search in Google Scholar

Cochran W.G., Cox G.M. (1957). Experimental Designs. 2nd ed. Wiley and Sons, New York.Search in Google Scholar

Cortinas L., Villaverde L., Galobart C., Baucells J., Codony R., Barroeta A.C. (2004). Fatty acid content in chicken thigh and breast as affected by dietary polyunsaturation level. Poultry Sci., 83: 1155–1164.Search in Google Scholar

Daley C.D., Abbott A., Doyle P.S., Nader G.A., Larson S. (2010). A review of fatty acid profiles and antioxidant content in grass-fed and grain-fed beef. Nutr. J., 9: 10.Search in Google Scholar

Delgado-Pando G., Alvarez C., Moran L. (2019). Editors. From farm to fork: New strategies for quality evaluation of fresh meat and processed meat products. J. Food Qual., 2019: 4656842.Search in Google Scholar

Fletcher D.L. (2002). Poultry meat quality. World. Poultry Sci. J., 58: 131–145.Search in Google Scholar

Guilford J., Fruchter B. (1978). Fundamental statistics in psychology and education (6th ed.). McGraw-Hill, New York.Search in Google Scholar

Gujarati D. (2009). Multicollinearity: What happens if the regressors are correlated. In: Basic Econometrics, Burr Ridge I.L., Dubuque I.A., Madison W.I. (eds). 4th ed. McGraw-Hill, Boston, USA, p. 363.Search in Google Scholar

Ghaedian R., Decker E.A., McClements D.J. (1997). Use of ultrasound to determine cod fillet composition. J. Food Sci., 62: 500–504.Search in Google Scholar

Ghaedian R., Coupland J.N., Decker E.A., McClements D.J. (1998). Ultrasonic determination of fish composition. J. Food Eng., 35: 323–337.Search in Google Scholar

Giffin J.L., Franks S.E., Rodriguez-Sosa J.R., Hahnel A., Bartlewski P.M. (2009). A study of morphological and haemodynamic determinants of testicular echotexture characteristics in the ram. Exp. Biol. Med., 234: 794–801.Search in Google Scholar

Giffin J.L., Bartlewski P.M., Hahnel. A. (2014). Correlations among ultrasonographic and microscopic characteristics of prepubescent ram lamb testes. Exp. Biol. Med., 239: 1606–1618.Search in Google Scholar

Haralick R.M. (1979). Statistical and structural approach to texture. Proc. IEEE, 67: 786–804.Search in Google Scholar

Hoskins P.R., Martin K., Thrush A. (2010). Diagnostic ultrasound: physics and equipment. 2nd ed. Cambridge University Press.10.1017/CBO9780511750885Search in Google Scholar

ISO 12966-2 (2017). Animal and vegetable fats and oils – Gas chromatography of fatty acid methyl esters – Part 2: Preparation of methyl esters of fatty acids.Search in Google Scholar

Kim N., Amin V., Wilson D., Rouse G., Udpa S. (1998). Ultrasound image texture analysis for characterizing intramuscular fat content of live beef cattle. Ultrason. Imaging, 20: 191–205.Search in Google Scholar

Kociołek M., Strzelecki M., Obuchowicz R. (2020). Does image normalization and intensity resolution impact texture classification? Comput. Med. Imaging Graph., 81: 101716.Search in Google Scholar

Koomkrong N., Theerawatanasirikul S., Boonkaewwan C., Jaturasitha S., Kayan A. (2015). Breed-related number and size of muscle fibres and their response to carcass quality in chickens. Ital. J. Anim. Sci., 14: 41–45.Search in Google Scholar

Liu X., Hart E.J., Petrik J.J., Nykamp S.G., Bartlewski P.M. (2008). Relationships between ultrasonographic image attributes, histomorphology and proliferating cell nuclear antigen (PCNA) expression of bovine antral follicles and corpora lutea ex situ. Reprod. Domest. Anim., 43: 27–34.Search in Google Scholar

Lock L., Bauman D.E. (2004). Modifying milk fat composition of dairy cows to enhance fatty acids beneficial to human health. Lipids, 39: 1197–1206.Search in Google Scholar

Marzec M.E., Wojtysiak D., Połtowicz K., Nowak J. (2020). ToF-SIMS spectrometry to observe fatty acid profiles of breast tissues in broiler chicken subjected to varied vegetable oil diet. Int. J. Mass Spectrom., 55: e4486.Search in Google Scholar

Materka A., Strzelecki M. (1998). Texture analysis methods – a review. University of Lodz, Institute of Electronics, COST B11 report.Search in Google Scholar

Meznaric M., Cvetko E. (2016). Size and proportions of slow-twitch and fast-twitch muscle fibers in human costal diaphragm. Biomed Res. Int., 5946520.10.1155/2016/5946520511651827891518Search in Google Scholar

Miles C.A., Fursey G.A.J., Fisher A.V., Page S.J. (1991). Estimation of lamb carcass composition from measurements of the speed of ultrasound in the soft tissues of live animals and carcasses. Meat Sci., 30: 245–256.Search in Google Scholar

Molinari F., Caresio C., Acharya U.R., Mookiah M.R.K., Minetto M.A. (2015). Advances in quantitative muscle ultrasonography using texture analysis of ultrasound images. Ultrasound Med. Biol., 41: 2520–2532.Search in Google Scholar

Newlacil I., Demkowicz M., Paczyńska K., Kuropka P., Szulc T. (2013). Factors affecting ultrasound intramuscular fat content in musculus longissimus dorsi of beef bulls estimated with BIA Pro Plus software. Ann. Anim. Sci., 13: 633–644.Search in Google Scholar

Nielsen P.K., Jensen B.R., Darvann T., Jørgensen K., Bakke M. (2006). Quantitative ultrasound tissue characterization in shoulder and thigh muscles – a new approach. BMC Musculoskelet. Disord., 7: 2.Search in Google Scholar

Park B., Whittaker A.D., Miller R.K., Bray D.E. (1994). Measuring intramuscular fat in beef with ultrasonic frequency analysis. J. Anim. Sci., 72: 117–125.Search in Google Scholar

Pazinato D.V., Stein B.V., de Almeida W.R., Werneck R.O., Junior P.R.M., Penatti O.A.B., Torres R.S., Menezes F.H., Rocha A. (2015). Pixel-level tissue classification for ultrasound images. IEEE J. Biomed. Health, 20: 256–267.Search in Google Scholar

Pena-Gonzalez E.M., Alarcon-Roja A.D., Renteria A., Garcia I., Santelano E., Quintero A., Luna L. (2017). Quality and sensory profiles of ultrasound-treated beef. Ital. J. Food Sci., 29: 463–475.Search in Google Scholar

Petracci M., Baeza E. (2011). Harmonization of methodologies for the assessment of poultry meat quality features. Worlds Poult. Sci. J., 67: 137–151.Search in Google Scholar

Pillen S. (2010). Skeletal muscle ultrasound. Eur. J. Transl. Myol., 1: 145–155.Search in Google Scholar

PN-75/A-04018/Az3 (2002). Agri-food products. Determination of nitrogen content by the Kjeldahl method and the conversion of protein. Publisher: Polish Committee for Standardization (in Polish).Search in Google Scholar

PN ISO 1442 : 2000 (2013). Meat and meat products-determination of moisture (reference method). Publisher: Polish Committee for Standardization.Search in Google Scholar

Reimers K., Reimers C.D., Wagner S., Paetzke I. (1993). Skeletal muscle sonography: a correlative study of echogenicity and morphology. J. Med. Ultrasound., 2: 73–77.Search in Google Scholar

Riley W.A. (1996). Physics and principles of ultrasound and instrumentation. Neurosonology. 1st ed. New York: Mosby-Year-Book.Search in Google Scholar

Sabetai M.M., Tegos T.J., Nicolaides A.N., Dhanjil S., Pare G.J., Stevens J.M. (2000). Reproducibility of computer-quantified carotid plaque echogenicity: can we overcome the subjectivity? Stroke, 31: 2189–2196.10.1161/01.STR.31.9.2189Search in Google Scholar

Schwarz T., Połtowicz K., Nowak J., Murawski M., Małopolska M., Andres K., Wojtysiak D., Jamieson M., Bartlewski P.M. (2019). Quantitative echotextural attributes of pectoralis major muscles in broiler chickens: Physicochemical correlates and effects of dietary fat source. Animals, 9: 306.Search in Google Scholar

Shahbandeh M. (2021). Chicken meat production worldwide from 2012 to 2021 (in 1,000 metric tons) https://www.statista.com/statistics/237637/production-of-poultry-meat-worldwide-since-1990/Search in Google Scholar

Slósarz P., Gut A., Stanisz M., Steppa R., Wojtkowski J., Dankow R. (2001). Assessment of intramuscular fat content in the longissimus dorsi muscle in live lambs on the basis of ultrasound image. Arch. Tierz., 44: 344–350.Search in Google Scholar

Smink W., Gerrits W.J., Hovenier R., Geelen M.J., Verstegen M.W., Beynen A.C. (2010). Effect of dietary fat sources on fatty acid deposition and lipid metabolism in broiler chickens. Poultry Sci., 89: 2432–2440.Search in Google Scholar

Smith D.P., Fletcher D.L. (1988). Chicken breast muscle fiber type and diameter as influenced by age and intramuscular location. Poultry Sci., 67: 908–913.Search in Google Scholar

Smulikowska S., Rutkowski A. (2005). Feeding standards for poultry. In: Nutritional requirements and nutritional value of feed. IV ed. Amended and Supplemented. IFiZZ PAN, Jabłonna, Poland.Search in Google Scholar

Sugiharto S., Isroli I., Yudiarti T., Widiastuti E. (2018). The effect of supplementation of multistrain probiotic preparation in combination with vitamins and minerals to the basal diet on the growth performance, carcass traits, and physiological response of broilers. Vet. World., 11: 240–247.Search in Google Scholar

Tegos T.J., Sabetai M., Nicolaides A., Pare G., Elatrozy T., Dhanjil S., Griffin M. (2000). Comparability of the ultrasonic tissue characteristics of carotid plaques. J. Med. Ultrasound., 19: 399–407.Search in Google Scholar

Tiidus P.M. (2008). Skeletal muscle damage and repair. Human Kinetics, 337 pp.10.5040/9781718209664Search in Google Scholar

Walker F.O., Cartwright M.S., Wiesler E.R., Caress J. (2004). Ultrasound of nerve and muscle. Clin. Neurophysiol., 115: 495–507.Search in Google Scholar

Zambiazi R.C., Przybylski R., Zambiazi M.W., Mendonça C.B. (2007). Fatty acid composition of vegetable oils and fats. B. Ceppa, 25: 111–120.Search in Google Scholar