[Abellán A., Salazar E., Vázquez J., Cayuela J. M., Tejada L. (2018). Changes in proteolysis during the dry-cured processing of refrigerated and frozen loin. LWT-Food Sci. Technol., 96: 507–512.]Search in Google Scholar
[Bartkiene E., Bartkevics V., Mozuriene E., Krungleviciute V., Novoslavskij A., Santini A., Rozentale I., Juodeikiene G., Cizeikiene D. (2017). The impact of lactic acid bacteria with antimicrobial properties on biodegradation of polycyclic aromatic hydrocarbons and biogenic amines in cold smoked pork sausages. Food Control, 71: 285–292.]Search in Google Scholar
[Belitz H. D., Grosch W., Schieberle P. (2009). Food Chemistry, 4th revised and extended edition. Springer-Verlag Berlin Heidelberg, pp. 341, 359, 386, 838, 903, 923, 975.]Search in Google Scholar
[Berardo A., Devreese B., De Maere H., Stavropoulou D. A., Van Royen G., Leroy F., De Smet S. (2017). Actin proteolysis during ripening of dry fermented sausages at different pH values. Food Chem., 221: 1322–1332.]Search in Google Scholar
[Bermúdez R., Franco D., Carballo J., Sentandreu M. Á., Lorenzo J. M. (2014). Influence of muscle type on the evolution of free amino acids and sarcoplasmic and myofibrillar proteins through the manufacturing process of Celta dry-cured ham. Food Res. Int., 56: 226–235.]Search in Google Scholar
[Breene W. M. (1975). Application of texture profile analysis to instrumental food texture evaluation. J. Texture Stud., 6: 53–82.]Search in Google Scholar
[Burdock G. A. (2010). Fenaroli’s Handbook of Flavor Ingredients, 6th ed. CRC Press Taylor & Francis Group, p. 54.]Search in Google Scholar
[Calik J., Krawczyk J., Świątkiewicz S., Gąsior R., Wojtycza K., Połtowicz K., Obrzut J., Puchała M. (2017). Comparison of the physicochemical and sensory characteristics of Rhode Island Red (R-11) capons and cockerels. Ann. Anim. Sci., 17: 903–917.]Search in Google Scholar
[Cebulska A. (2018). Quality and dietary value of pork meat of the Puławska and Złotnicka Spotted breeds, and commercial fattening pigs. Ann. Anim. Sci., 18: 281–291.]Search in Google Scholar
[Chang-Yu Z., Ying W., Dao-Dong P., Jin-Xuan C., Yin-Ji C., Yuan L., Yang-Ying S., Chang-Rong O. (2017). The changes in the proteolysis activity and the accumulation of free amino acids during Chinese traditional dry-cured loins processing. Food Sci. Biotechnol., 26: 679–687.]Search in Google Scholar
[Corral S., Salvador A., Belloch C., Flores M. (2015). Improvement the aroma of reduced fat and salt fermented sausages by Debaromyces hansenii inoculation. Food Control, 47: 526–535.]Search in Google Scholar
[Coton E., Coton M. (2005). Multiplex PCR for colony direct detection of Gram positive histamineand tyramine-producing bacteria. J. Microbiol. Methods, 63: 296–304.]Search in Google Scholar
[Debrecéni O., Lípová P., Bučko O., Cebulska A., Kapelánski W. (2018). Effect of pig genotypes from Slovak and Polish breeds on meat quality. Arch. Anim. Breed., 61: 99–107.]Search in Google Scholar
[Degnes K. F., Kvitvang H. F. N., Haslene-Hox H., Aasen I. M. (2017). Changes in the profiles of metabolites originating from protein degradation during ripening of dry cured ham. Food Bioprocess Tech., 10: 1122–1130.]Search in Google Scholar
[Dunkel A., Steinhaus M., Kotthoff M., Nowak B., Krautwurst D., Schieberle P., Hofmann T. (2014). Nature’s chemical signatures in human olfaction: a foodborne perspective for future biotechnology. Angew. Chem. Int. Ed. Engl., 53: 7124–7143.]Search in Google Scholar
[Fabri R., Bergonzini E. (1981). Performance of pure and cross-bred Spotted Poland pigs. Rivista di Suinicoltura, 22: 25–33.]Search in Google Scholar
[Fadda S., López C., Vignolo G. (2010). Role of lactic acid bacteria during meat conditioning and fermentation. Peptides generated as sensorial and hygienic biomarkers. Meat Sci., 86: 66–79.]Search in Google Scholar
[FAO (2003). Food energy methods of analysis and conversion factors. Food and Agriculture Organization, Rome.]Search in Google Scholar
[Ferrocino I., Bellio A., Giordano M., Macori G., Romano A., Rantsiou K., Decastelli L., Cocolin L. (2017). Shotgun metagenomics and volatilome profile of the microbiota of fermented sausages. Appl. Environ. Microbiol., 84: 1–14.]Search in Google Scholar
[Flavornet (2020). http://www.flavornet.org/flavornet.html (retrieved 17.01.2020).]Search in Google Scholar
[Flores M., Toldrá F. (2011). Microbial enzymatic activities for improved fermented meats. Food Sci. Technol., 22: 81–90.]Search in Google Scholar
[Flores M., Aristoy M. C., Toldrá F. (1997). Curing agents affect aminopeptidase activity from porcine skeletal muscle. Z. Lebensm. Unters For., 205: 343–346.]Search in Google Scholar
[Folch J., Lees M., Sloane S. G. H. (1957). A simple method for the isolation and purification of total lipids from animal tissues. J. Biol. Chem., 226: 497–509.]Search in Google Scholar
[Gąsior R., Wojtycza K. (2016). Sense of smell and volatile aroma compounds and their role in the evaluation of the quality of products of animal origin – a review. Ann. Anim. Sci., 16: 3–31.]Search in Google Scholar
[Gorska E., Nowicka K., Jaworska D., Przybylski W., Tambor K. (2017). Relationship between sensory attributes and volatile compounds of Polish dry-cured loin. Asian-Austral. J. Anim. Sci., 30: 720–727.]Search in Google Scholar
[Hospital X., Barballo J., Fernandez M., Arnau J., Gratacos M., Hierro E. (2015). Technological implications of reducing nitrate and nitrite levels in dry-fermented sausages: Typical microbiota, residual nitrate and nitrite and volatile profile. Food Control, 57: 275–281.]Search in Google Scholar
[Innocente N., Biasutti M., Padovese M., Moret S. (2007). Determination of biogenic amines in cheese using HPLC technique and direct derivation of acid extract. Food Chem., 101: 1285–1289.]Search in Google Scholar
[Janiszewski P., Grześkowiak E., Szulc K., Borzuta K., Lisiak D. (2015). Effect of crossing Zlotnicka Spotted pigs with Duroc and Polish Large White breeds on quality of selected meat products. Food Sci. Technol. Quality, 5: 109–120.]Search in Google Scholar
[Jerkovic I., Kovacevic D., Subaric D., Marjianovic Z., Mastanjevic K., Suman K. (2010). Authentication study of volatile flavour compounds composition in Slavonian traditional dry fermented salami “kulen”. Food Chem., 119: 813–822.]Search in Google Scholar
[Kaban G., Bayrak D. (2015). The effects of using turkey meat on qualitative properties of heattreated sucuk. Czech J. Food Sci., 33: 377–382.]Search in Google Scholar
[Kapelański W., Buczyński T. J., Bocian M. (2006). Slaughter value and meat quality in the Polish native Zlotnicka Spotted pig. Anim. Sci. Pap. Rep., 24: 7–13.]Search in Google Scholar
[Karpiński P., Łątkowska M., Kruszewski B., Ku ź ma P., Obiedziński M. W. (2015). Profile of volatile compounds in European dry-cured hams as indicator of their quality and authenticity (in Polish). Żywność. Nauka. Technologia. Jakość, 2: 47–61.]Search in Google Scholar
[Kemp C. M., Sensky P. L., Bardsley R. G., Buttery P. J., Parr T. (2010). Tenderness – an enzymatic view. Meat Sci., 84: 248–256.]Search in Google Scholar
[Koło ż yn-Krajewska D., Dolatowski Z. (2012). Probiotic meat products and human nutrition. Proc. Biochem., 47: 1761–1772.]Search in Google Scholar
[Krupiński J. (2011). Conservation of genetic resources of livestock and wild animals. Warszawa, Poland, PWRiL.]Search in Google Scholar
[Kuchroo C. V., Ramilly I. P., Fox P. F. (1983). Assessment of proteolysis in cheese by reaction with trinitrobenzensulphonic acid. J. Food Technol., 7: 129–133.]Search in Google Scholar
[Latorre-Moratalla M. L., Bosch-Fusté J., Bover-Cid S., Aymerich T., Vidal-Carou M. C. (2011). Contribution of enterococci to the volatile profile of slightly-fermented sausages. LWT-Food Sci. Technol., 44: 145–152.]Search in Google Scholar
[Leffingwell and Associates. Odor and flavor detection thresholds in water. http://www.leffingwell.com/odorthre.htm (retrieved 17.01.2020).]Search in Google Scholar
[Leroy F., Verluyten J., De Vuyst L. (2006). Functional meat starter cultures for improved sausage fermentation. Int. J. Food Microbiol., 106: 270–285.]Search in Google Scholar
[Leroy S., Gimmarinaro P., Chacornac J. P., Lebert I., Talon R. (2010). Biodiversity of indigenous staphylococci of naturally fermented dry sausages and manufacturing environments of small-scale processing units. Food Microbiol., 27: 294–301.]Search in Google Scholar
[Lucas P. M., Wolken W. A. M., Claisse O., Lolkema J. S., Lonvaud-Funel A. (2005). Histamine-producing pathway encoded on an unstable plasmid in Lactobacillus hilgardii 0006. Appl. Environ. Microbiol., 71: 1417–1424.]Search in Google Scholar
[Lv S. D., Wu Y., Song Y. Z., Zhou J. S., Lian M., Wang C., Liu L., Meng Q. X. (2015). Multivariate analysis based on GC-MS fingerprint and volatile composition for the quality evaluation of pu-erh green tea. Food Anal. Methods, 8: 321–333.]Search in Google Scholar
[Majcher M. A., Kaczmarek A., Klensporf-Pawlik D., Pikul J., Jeleń H. H. (2015). SPME-MS-based electronic nose as a tool for determination of authenticity of PDO cheese, oscypek. Food Anal. Methods, 8: 2211–2217.]Search in Google Scholar
[Marney L. C., Siegler W. C., Parsons P. A., Hoggard J. C., Wright B. W., Synovec R. E. (2013). Tile-based Fisher-ratio software for improved feature selection analysis of comprehensive two-dimensional gas chromatography-time-of-flight mass spectrometry data. Talanta, 115: 887–895.]Search in Google Scholar
[Martínez-Arellano I., Flores M., Toldrá F. (2016). The ability of peptide extracts obtained at different dry cured ham ripening stages to bind aroma compounds. Food Chem., 196: 9–16.]Search in Google Scholar
[Martínez-Onandi N., Rivas-Cañedo A., Picon A., Nuñez M. (2016). Influence of physicochemical parameters and high pressure processing on the volatile compounds of Serrano dry-cured ham after prolonged refrigerated storage. Meat Sci., 122: 101–108.]Search in Google Scholar
[Marušić Radovčić N., Vidaček S., Janči T., Medić H. (2016). Characterization of volatile compounds, physico-chemical and sensory characteristics of smoked dry-cured ham. J. Food Sci. Technol., 53: 4093–4105.]Search in Google Scholar
[Migdał W., Radivić Č., Ž ivković V., Gwiazda E., Migdał Ł., Migdał A., Walczycka M., Węsierska E., Zając M., Tkaczewska J., Kulawik P., Krępa-Stefanik K. (2017). Quality of meat from native pigs. In: Modern trends in livestock production, Petrović M.M. (ed.). Institute for Animal Husbandry, Serbia, pp. 189–203.]Search in Google Scholar
[Narváez-Rivas M., Pablos F., Jurado J. M., León-Camacho M. (2011). Authentication of fattening diet of Iberian pigs according to their volatile compounds profile from raw subcutaneous fat. Anal. Bioanal. Chem., 399: 2115–2122.]Search in Google Scholar
[Nicolotti L., Cordero C., Cagliero C., Liberto E., Sgorbini B., Rubiolo P., Bicchi B. (2013). Quantitative fingerprinting by headspace – Two-dimensional comprehensive gas chromatography–mass spectrometry of solid matrices: Some challenging aspects of the exhaustive assessment of food volatiles. Anal. Chim. Acta, 798: 115–125.]Search in Google Scholar
[Olivares A., Navarro J. L., Flores M. (2009). Establishment of the contribution of volatile compounds to the aroma of fermented sausages at different stages of processing and storage. Food Chem., 115: 1464–1472.]Search in Google Scholar
[Olivares A., Navarro J. L., Salvador A., Flores M. (2010). Sensory acceptability of slow fermented sausages based on fat content and ripening time. Meat Sci., 8: 251–257.]Search in Google Scholar
[Ordóñez J. A., Hierro E. M., Bruna J. M., Dela Hoz L. (2010). Changes in the components of dry-fermented sausages during ripening. Crit. Rev. Food Sci. Nutr., 39: 329–367.]Search in Google Scholar
[Ravyts F., De Vuyst L., Leroy F. (2012). Bacterial diversity and functionalities in food fermentations. Eng. Life Sci., 12: 356–357.]Search in Google Scholar
[Resconi V. C., Campo M. M., Montossi F., Ferreira V., Sañudo C., Escudero A. (2010). Relationship between odor-active compounds and flavor perception in meat from lambs fed different diets. Meat Sci., 85: 700–706.]Search in Google Scholar
[Rosmini M. R., Perlo F., Pérez-Alvarez J. A., Pagán-Moreno M. J., Gago-Gago A., López-Santovena F., Aranda-Catalá V. (1996). TBA test by an extractive method applied to ‘pate’. Meat Sci., 42: 103–110.]Search in Google Scholar
[Satomi M., Furushita M., Oikawa H., Yoshikawa-Takahashi M., Yano Y. (2008). Analysis of a 30 kbp plasmid encoding histidine decarboxylase gene in Tetragenococcus halophilus isolated from fish sauce. Int. J. Food Microbiol., 126: 202–209.]Search in Google Scholar
[Spano G., Russo P., Lonvaud-Funel A., Lucas P., Alexandre H., Grandvalet C., Coton E., Coton M., Barnavon L., Bach B., Rattray F., Bunte A., Magni C., Ladero V., Alvarez M., Fernández M., Lopez P., Palencia P. F., Corbi A., Trip H., Lolkema J. S. (2010). Biogenic amines in fermented foods. Eur. J. Clin. Nutr., 64: 95–100.]Search in Google Scholar
[Spaziani M., Del Torre M., Stecchini M. L. (2009). Changes of physicochemical, microbiological and textural properties during ripening of Italian low-acid sausages. Proteolysis, sensory and volatile profiles. Meat Sci., 81: 77–85.]Search in Google Scholar
[Szyndler-Nędza M., Luciński P., Skrzypczak E., Szulc K., Bajda Z. (2017). Pigs of native breeds – status of breeding and evaluation results. In: Protection of genetic resources of domestic breeds of pigs – status of breeding and results of evaluation for 2008, Eckert R. (ed.). IZ PIB, Kraków, Poland, pp. 37–39.]Search in Google Scholar
[The Good Scents Company. http://www.thegoodscentscompany.com (retrieved 17.01.2020).]Search in Google Scholar
[Toldrá F., Aristoy M. C., Flores M. (2000). Contribution of muscle aminopeptidases to flavor development in dry cured ham. Food Res. Int., 33: 181–185.]Search in Google Scholar
[Tyra M., Ż ak G., Eckert R., Mitka I. (2015). Daily feed intake and the effectiveness of its use in pigs fattening. Sci. Ann. Zootech., 42: 127–134.]Search in Google Scholar
[Van Gemert L. J. (2011). Odour Thesholds. Compilation of odour threshold values in air, water and other media; Oliemans Punter & Partners BV: Utrecht, Netherlands.]Search in Google Scholar
[Węsierska E., Szołtysik M., Rak L. (2013). Physico-chemical, biochemical and microbiological properties of traditional Polish pork fermented products during ripening. Food Bioprocess Tech., 6: 2986–2995.]Search in Google Scholar
[Węsierska E., Szmańko T., Krzysztoforski K. (2014). Ripening effect on chemical composition, microstructure, collagen solubility, shear force, texture parameters and sensory evaluation: a case study of “kumpia wieprzowa”. CYTA – J. Food, 12: 80–84.]Search in Google Scholar
[Wójciak K. M., Dolatowski Z. J. (2012). Oxidative stability of fermented meat products. Acta Sci. Pol. Technol. Aliment., 11: 99–109.]Search in Google Scholar
[Yalinkiliç B., Kaban G., Ertekín O., Mükerrem K. (2015). Determination of volatile compounds of sucuk with different orange fiber and fat level. J. Faculty Vet. Med., 21: 233–239.]Search in Google Scholar
[Yim D. G., Hong D. I., Chung K. Y. (2016). Quality characteristics of dry-cured ham made from two different three-way crossbred pigs. Asian-Austral. J. Anim. Sci., 29: 257–262.]Search in Google Scholar
