Marcela Santarelli
University of Parma
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Featured researches published by Marcela Santarelli.
Applied and Environmental Microbiology | 2008
Monica Gatti; Juliano De Dea Lindner; Angela De Lorentiis; Benedetta Bottari; Marcela Santarelli; Valentina Bernini; Erasmo Neviani
ABSTRACT Microbial succession during Parmigiano-Reggiano cheesemaking was monitored by length heterogeneity PCR (LH-PCR), considering the intact and lysed cells at different stages of cheese production and ripening. When starter species underwent autolysis, species coming from milk were able to grow. For the first time, the LH-PCR technique was applied to study a fermented food.
Journal of Dairy Science | 2008
Marcela Santarelli; Monica Gatti; Camilla Lazzi; Valentina Bernini; G.A. Zapparoli; Erasmo Neviani
This work aimed to investigate the effects of thermal treatments and yeast extract addition on the composition of the microbial community of natural whey starters for Grana Padano cheese. Different natural whey starter samples were held at 4 degrees C for 24 h (cooling treatment), or at -20 degrees C for 24 h (freezing treatment) to evaluate the possibility of conservation, or at 54 degrees C for 1 h (heat treatment) to evaluate the effect of the temperature commonly used during curd cooking. Separately, another set of samples was enriched with 0.3, 0.5, and 1.0% (wt/vol) of yeast extract to study its effect on the growth of lactic acid bacteria (LAB) in the starter. The new approach in this study is the use of 2 culture-independent methods: length heterogeneity (LH)-reverse transcription (RT)-PCR and fluorescence microscopy. These techniques allowed us to easily, quickly, and reproducibly assess metabolically active LAB in the control and treated samples. The LH-RT-PCR technique distinguished microorganisms based on natural variations in the length of 16S rRNA amplified by RT-PCR, as analyzed by using an automatic gene sequencer. Fluorescence microscopy counts were performed by using a Live/Dead BacLight bacterial viability kit. The repeatability of LH-RT-PCR showed that this technique has great potential to reveal changes in the microbial community of natural whey starters for Grana Padano cheese. All species showed low sensitivity to cold (4 degrees C). However, after the freezing (-20 degrees C) and heating (54 degrees C) treatments, different behaviors of the species were reported, with significant changes in their viability and relative composition. Heating treatment during curd cooking profoundly affected the viability and composition of the community that remained in the cheese and that consequently modified the microbial population. At the same time, this treatment produced the selection of LAB in whey and could be considered as the first step in natural whey starter production. Addition of yeast extract stimulated the growth of Streptococcus thermophilus and Lactobacillus delbrueckii ssp. lactis to the detriment of Lactobacillus helveticus species. Because the yeast extract altered the microflora balance, whey starter conservation at -20 degrees C and yeast extract addition cannot be suggested as technological innovations.
Journal of Applied Microbiology | 2010
Benedetta Bottari; Marcela Santarelli; Erasmo Neviani; Monica Gatti
Aims: The aim of this work was to obtain a deeper insight into the knowledge of microbial composition of Parmigiano Reggiano natural whey starters through different culture‐independent methods.
Food Microbiology | 2013
Tomislav Pogačić; Andrea Mancini; Marcela Santarelli; Benedetta Bottari; Camilla Lazzi; Erasmo Neviani; Monica Gatti
The aim of this study was to explore diversity and dynamic of indigenous LAB strains associated with a long ripened hard cheese produced from raw milk and undefined natural starter such as PDO Grana Padano cheese. Samples of milk, curd, natural whey culture and cheeses (2nd, 6th, 9th and 13th months of ripening) were collected from 6 cheese factories in northern Italy. DNA was extracted from each sample and from 194 LAB isolates. tRNA(Ala)-23S rDNA-RFLP was applied to identify isolates. Strain diversity was assessed by (GTG)5 rep-PCR and RAPD(P1)-PCR. Finally, culture-independent LH-PCR (V1-V2 16S-rDNA), was considered to explore structure and dynamic of the microbiota. Grana Padano LAB were represented mainly by Lactobacillus rhamnosus, Lactobacillus casei, Lactobacillus paracasei, Lactobacillus delbrueckii, Lactobacillus helveticus and Pediococcus acidilactici, while the structure and dynamic of microbiota at different localities was specific. The strength of this work is to have focused the study on isolates coming from more than one cheese factories rather than a high number of isolates from one unique production. We provided a valuable insight into inter and intraspecies diversity of typical LAB strains during ripening of traditional PDO Grana Padano, contributing to the understanding of specific microbial ecosystem of this cheese.
Systematic and Applied Microbiology | 2013
Marcela Santarelli; Benedetta Bottari; Camilla Lazzi; Erasmo Neviani; Monica Gatti
Grana Padano (GP) is a Protected Designation of Origin cheese made with raw milk and natural whey culture (NWC) that is characterised by a long ripening period. In this study, six GP productions were considered in order to evaluate the trend of microbial dynamics and compare lactic acid bacteria (LAB) population levels in cheeses during the entire cheese-making process. To reach this goal, for each GP production, samples of vat raw milk, NWC and cheeses at 48h, 2, 6, 9 and 13 months were subjected to plate counts and direct counts by fluorescence microscopy, as well as amplicon length heterogeneity-PCR (LH-PCR). Statistical analysis was applied to the results and ecological indices were estimated. It was demonstrated that the LAB able to grow in the cheese-environment conditions could arise from both raw milk and NWC. Starter lactobacilli (SLAB) from NWC were the main species present during acidification, and non-starter LAB (NSLAB), mainly from milk but also from NWC, were able to grow after brining and they dominated during ripening. The peak areas of LH-PCR profiles were used to determine ecological indices during manufacture and ripening. Among cheese ecosystems with different ageing times, diversity, Evenness and Richness were different, with highest bacterial growth and diversity occurring in cheese ripening at 2 months. At this time point, which seemed to be a crucial moment for GP microbial evolution, cell lysis of both SLAB and NSLAB was also observed. Sampling modality and statistical analysis gave greater significance to the results used to describe the microbiological characteristics of a cheese recognised worldwide.
Annals of Microbiology | 2011
Monica Gatti; Benedetta Bottari; Marcela Santarelli; Erasmo Neviani
Twenty-one natural whey starters, collected from dairy factories located in six provinces of the Grana Padano production area, were characterized. Basic techniques, such as acidity evaluation and microbial plate count, together with more complex methods such as the Live/Dead® BacLight™ bacterial viability kit, have been used. Seven parameters, including pH, Soxhlet Henkel degrees, microbial plate count in Man Rogosa Sharpe medium and Whey Agar medium, together with count of total, viable and non-viable cells, have been adopted to produce sunray plots. One plot for each natural whey starter sample was obtained by characterizing the status of the microbial culture and compared with three natural whey starters prepared in the laboratory. In this way, a sunray trace is suggested to define the traits of a good natural whey starter. Another multivariate technique, principal component analysis, was applied, and it should be possible to conclude that, for this particular dataset composed of 24 objects and 7 variables, PCA allowed the highlighting of the good and bad samples, while sunray plots, even if remaining only a descriptive and explorative analysis, allowed the better visualizing of the differences among all the samples.
Food Technology and Biotechnology | 2011
J. de D. Lindner; Marcela Santarelli; Caroline T. Yamaguishi; Carlos Ricardo Soccol; Erasmo Neviani; Ashok Pandey; C. Larroche; Vanete Thomaz-Soccol
Trends in Food Science and Technology | 2015
Benedetta Bottari; Marcela Santarelli; Erasmo Neviani
Dairy Science & Technology | 2013
Marcela Santarelli; Benedetta Bottari; Massimo Malacarne; Camilla Lazzi; Stefano Sforza; Andrea Summer; Erasmo Neviani; Monica Gatti
New Biotechnology | 2014
Stefania Baldassarre; Stefano Sforza; Barbara Prandi; Marcela Santarelli; Neha Babbar; Kathy Elst; Monica Gatti