Autochthonous Cultures to Improve Safety and Standardize Quality of Traditional Dry Fermented Meats
Abstract
:1. Introduction
2. Technologically Relevant Microorganisms in Dry Fermented Meats
2.1. LAB Occurring in Dry Fermented Meats
2.2. Coagulase Negative Staphylococci in Fermented Dry Meats
2.3. Yeasts and Molds in Fermented Dry Sausages
2.4. Diversity of Naturally Occurring Technologically Relevant Microorganisms in Dry Fermented Meats
3. Safety Concerns in Traditional Fermented Dry Meats
3.1. Microbial Pathogens
3.2. Nitrosoamines
3.3. Biogenic Amines
3.4. Mycotoxins
3.5. Polycyclic Aromatic Hydrocarbons
4. Effect of Autochthonous Microbial Cultures on Safety and Quality of Dry Fermented Sausages
4.1. Effects of Autochthonous Cultures on Safety of Dry Fermented Sausages
4.2. Effects of Autochthonous Cultures on Sensory Attributes of Dry Fermented Sausages
4.3. Autochthonous Probiotics in Dry Fermented Sausages
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Microbial Strains | Product | Effect | Reference * |
---|---|---|---|
S. simulans QB7 | Qianwufu fermented sausage, Guizhou province, China | reduced growth of undesirable bacteria | Li et al. [44] |
L. curvatus 8427, L. plantarum 7423, L. sakei 8416, 4413 and 8426 | Greek fermented sausages | inhibition of undesirable microorganisms | Baka et al. [83] |
L. curvatus 54M16 | fermented sausages of Campania region, Italy | lower numbers of Enterobacteriaceae | Casaburi et al. [84] |
L. sakei CV3C2 and CECT7056, S. equorum S2M7, S. xylosus CECT7057, yeast strain 2RB4 | Painho da Beira Baixa, Portugal | decrease in pH, Enterobacteriaceae, L. monocytogenes and total Bas | Dias et al. [85] |
L. sakei CV3C2, S. equorum S2M7, yeast 2RB4 | Paio do Alentejo, Portugal | decrease in L. monocytogenes counts and vasoactive amines tryptamine and β-phenylethylamine content | Dias et al. [86] |
L. sakei CV3C2 and CECT7056, S. equorum S2M7, S. xylosus CECT7057, yeast strain 2RB4 | Paio do Alentejo, Portugal | decrease in pH, L. monocytogenes counts and total BA content | Dias et al. [87] |
L. sakei, S. epidermidis | Harbin sausage, China | decrease in tyramine content | Dong et al. [78] |
L. curvatus 54M16 | fermented sausages of Campania region, Italy | total inhibition of L. monocytogenes native from raw materials, inhibition of Brochothrix, Psychrobacter, Pseudomonas and Enterobacteriaceae | Giello et al. [88] |
L. curvatus, L. sakei, P. pentosaceus, S. xylosus | Harbin dry sausage, China | decrease in aw | Hu et al. [89] |
L. curvatus SYS29, L. lactis HRB0, L. plantarum MDJ2, L. sakei HRB10, W. hellenica HRB6 | traditional dry sausage, China | decrease in pH and aw, increase in LAB counts | Hu et al. [90] |
L. plantarum S50, S51, S72, S74, S85 | Sucuk, Turkey | Inhibition of L. monocytogenes, rapid decrease in pH | Kamiloglu et al. [91] |
D. hansenii | Salsiccia Sarda, Italy | Anti-mold effect | Murgia et al. [92] |
L. sakei 205 | Salchichón, Spain | decrease in L. monocytogenes counts | Martín et al. [93] |
D. hansenii | dry-cured meat products | decrease in aflatoxin formation by Aspergillus parasiticus | Peromingo et al. [94] |
L. sakei, P. pentosaceus, S. carnosus, S. xylosus | Sichuan sausage, China | decreased levels of histamine, putrescine, tyramine, cadaverine and residual nitrites | Ren et al. [95] |
L. sakei/S. equorum SA25 L. sakei LS131/S. saprophyticus SB12 | Galician Chorizo, Spain | pH decrease, increase in free amino acids and decrease of total BAs by approximately 20% | Rodríguez et al. [96] |
L. plantarum, L. salivarius | traditional smoked horsemeat sausage, China | decrease in all indigenous microorganisms, including Enterobacter cloacae, Enterococcus faecium, Pseudomonas spp. and Weissella and in total BAs and histamine | Zhang et al. [97] |
Microbial Strains | Product | Effect | Reference * |
---|---|---|---|
L. fermentum BL11, L. sakei BL6, P. acidilactici BP2 | Beef jerky, China | Lower pH and indicators of lipid and protein oxidation, higher VOC formation from carbohydrates for L. sakei; higher VOC formation from lipid β-oxidation and amino acid metabolism, esterase activity and acceptability score for P. acidilactici | Wen et al. [20] |
S. simulans QB7 | Qianwufu fermented sausage, Guizhou province, China | reduced growth of undesirable bacteria | Li et al. [44] |
D. hansenii M4 and P2 | dry-cured fermented sausages | strain P2 decreased lipid oxidation and increased acid compounds, strain M4 increased sulphur containing compounds, no differences in consumer acceptance | Cano-García et al. [50] |
L. sakei, P. pentosaceus, S. xylosus | Salame Piemonte, Italy | improvement of the sensory properties | Franciosa [32] |
L. plantarum MF1291 and MF 1298, L. pentosus MF1300 | Traditional Norwegian salami | 19 sensory parameters comparable to the commercial starter culture L. sakei HJ5 | Klingberg et al. [59] |
L. curvatus 8427, L. plantarum 7423, L. sakei 8416, 4413 and 8426 | Greek fermented sausages | prevention of lipid oxidation; higher scores for all sensory attributes | Baka et al. [83] |
L. curvatus 54M16 | fermented sausages of Campania region, Italy | more intense ripened flavor | Casaburi et al. [84] |
L. sakei CV3C2 and CECT7056, S. equorum S2M7, S. xylosus CECT7057, yeast strain 2RB4 | Painho da Beira Baixa, Portugal | higher scores in sensory attributes | Dias et al. [85] |
L. sakei CV3C2 and CECT7056, S. equorum S2M7, S. xylosus CECT7057, yeast strain 2RB4 | Paio do Alentejo, Portugal | negative effect on the sensory characteristics of fermented sausages | Dias et al. [86] |
L. curvatus, L. sakei, P. pentosaceus, S. xylosus | Harbin dry sausage, China | increase in hardness and springiness, higher percentages of aldehydes, ketones, alcohols, acids and esters | Hu et al. [89] |
L. curvatus SYS29, L. lactis HRB0, L. plantarum MDJ2, L. sakei HRB10, W. hellenica HRB6 | traditional dry sausage, China | increase in VOC content, decrease in total content of free amino acids, enrichment of pleasant odors for L. sakei and W. hellenica | Hu et al. [90] |
L. sakei, P. pentosaceus, S. carnosus, S. xylosus | Sichuan sausage, China | lower hardness and chewiness, increased springiness; improved color and sensory attributes | Ren et al. [95] |
L. sakei LS131/S. equorum SA25 or L. sakei LS131/S. saprophyticus SB12 | Galician Chorizo, Spain | increment in the α-amino acid nitrogen, total basic volatile nitrogen and free amino acids, improvement of color | Rodríguez et al. [96] |
L. brevis R4, L. curvatus R5, L. fermentum R6, P. pentosaceus R1 | Harbin dry sausage | P. pentosaceus hydroxyl radical and 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical scavenging activity, inhibition of lipid peroxidation, high SOD and glutathione peroxidase (GSH-Px) activities | Chen et al. [98] |
L. brevis R4, L. curvatus R5, L. fermentum R6, P. pentosaceus R1 | Harbin dry sausage | P. pentosaceus strongest proteolysis activity, highest formation of soluble peptides and free amino acids, VOCs from sarcoplasmic proteins | Chen et al. [99] |
S. xylosus SX16, L. plantarum CMRC6 | Chinese Dong fermented pork (Nanx Wudl) | acceleration of acidification and proteolysis, increase in total free amino acids and essential free amino acids Phe, Ile and Leu, increase in 3-methyl-1-butanol | Chen et al. [100] |
L. plantarum L125 | traditional Greek dry-fermented sausage | desiderable technological characteristics | Pavli et al. [101] |
L. fermentum BL11, L. sakei BL6, P. acidilactici BP2 | Beef jerky, China | decrease in lipid autoxidation-derived aldehydes; increment of esters for P. acidilactici; strain-specific flavour profiles | Wen et al. [102] |
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Rossi, F.; Tucci, P.; Del Matto, I.; Marino, L.; Amadoro, C.; Colavita, G. Autochthonous Cultures to Improve Safety and Standardize Quality of Traditional Dry Fermented Meats. Microorganisms 2023, 11, 1306. https://doi.org/10.3390/microorganisms11051306
Rossi F, Tucci P, Del Matto I, Marino L, Amadoro C, Colavita G. Autochthonous Cultures to Improve Safety and Standardize Quality of Traditional Dry Fermented Meats. Microorganisms. 2023; 11(5):1306. https://doi.org/10.3390/microorganisms11051306
Chicago/Turabian StyleRossi, Franca, Patrizia Tucci, Ilaria Del Matto, Lucio Marino, Carmela Amadoro, and Giampaolo Colavita. 2023. "Autochthonous Cultures to Improve Safety and Standardize Quality of Traditional Dry Fermented Meats" Microorganisms 11, no. 5: 1306. https://doi.org/10.3390/microorganisms11051306
APA StyleRossi, F., Tucci, P., Del Matto, I., Marino, L., Amadoro, C., & Colavita, G. (2023). Autochthonous Cultures to Improve Safety and Standardize Quality of Traditional Dry Fermented Meats. Microorganisms, 11(5), 1306. https://doi.org/10.3390/microorganisms11051306