Development of Innovative Vitamin D Enrichment Designs for Two Typical Italian Fresh Cheeses: Burrata and Giuncata.

The aim of this research was to develop innovative cheeses fortified with vitamin D3 (VD3). Formulation studies and analyses of textural properties and chemicals were carried out for these developments. Two traditional Italian varieties of cheese (giuncata and burrata) were studied. For giuncata, the fortification of milk for cheese production provided a VD3 retention level of 43.9 ± 0.6% in the food matrix. For burrata, the VD3 ingredient was incorporated into the creamy inner part after mixing, maintaining the textural quality of the product (adhesiveness 4.3 ± 0.4 J × 10-3; firmness 0.7 ± 0.0 N; and cohesiveness 0.8 ± 0.2). The optimized enrichment designs allowed to obtain homogenous contents of VD3 during the production of giuncata (0.48 ± 0.01 µg/g) and burrata cheeses (0.32 ± 0.02 µg/g). Moreover, analyses revealed the high stability of VD3 during the storage of the two fortified cheese types (2 weeks, 4 °C). These fortification designs could be implemented at an industrial scale to obtain new cheese types enriched in VD3 and thus contribute to the reduction in VD deficiency prevalence.

Development of functional whey cheese enriched in vitamin D3: nutritional composition, fortification, analysis, and stability study during cheese processing and storage.

"Ricotta" cheese is a traditional and popular Italian fresh whey cheese commonly produced from cow's milk. Food fortification is an efficient strategy to reduce the high global prevalence of vitamin D deficiency. This study aims to study the chemical-nutritional analysis of ricotta cheese and to assess its suitability as a dairy matrix for vitamin D fortification. The chemical-nutritional analyses revealed that ricotta cheese is a good source of proteins (7.8 g/100 g) with high levels of branched-chain amino acids (1.8 g/100 g). Moreover, ricotta contains high levels of calcium (0.4 g/100 g) and phosphorus (0.2 g/100 g). 50 mg of vitamin D3 were added to 95 kg of cheese reaching a mean fortification level of 41.4 ± 4.0 µg/100 g of ricotta cheese. The fortification study showed that vitamin D homogenously distributes in ricotta cheese after the homogenisation process. Moreover, vitamin D3 has high heat stability (93.8 ± 1.8%) and remains stable throughout the shelf-life of the fortified food. This study demonstrates that ricotta cheese represents an ideal alternative dairy matrix for vitamin D3 fortification.

Influence of modified governing liquid on shelf-life parameters of high-moisture mozzarella cheese.

The roles of mesophilic lactobacilli in cheese manufacturing and ripening have been widely studied, but their impacts, especially as additives in preserving liquids, on the high-moisture mozzarella cheese quality parameters remained underexplored. The current study studied and compared the effects of four preserving liquid formulations - brine solution (sodium chloride, as control), a salt mixture solution, and two lactobacilli solutions (Lactiplantibacillus plantarum IMC 509 in brine solution) or SYNBIO® (a 1:1 ratio of Lacticaseibacillus rhamnosus IMC 501 and Lacticaseibacillus paracasei IMC 502) - on the microbial, chemical (volatile fatty acids), physicochemical (moisture, weight, pH, colour), texture (adhesiveness, hardness, cohesiveness, gumminess, springiness, chewiness) and sensorial qualities of mozzarella stored for 30 days at 4 °C. The quality of the governing solution, including microbial content, lactobacilli viability, pH, turbidity, and smell, was also monitored. For the first 10 days of storage, all samples demonstrated similar physicochemical variations: the firmness and chewiness of the mozzarella lessened, the pH values of the liquid decreased, but cheese microbial growth increased, as did the levels of free fatty acids, the mozzarella pH values and skin whiteness. At day 20, mozzarella stored in mesophilic lactobacilli liquid, especially SYNBIO®, had a spongy structure, tasted more bitter and sour, and had lower pH values than mozzarella in the simple brine solution. Moreover, the cheese sample and liquid of SYNBIO® also presented higher coliform and Pseudomonas spp. counts than that detected in the control, the SYNBIO® liquid, especially in the later period of storage, exhibited a yogurt smell and increased turbidity. By contrast, Mozzarella packed into salt mixture liquid exhibited somewhat more adhesiveness and gumminess, a saltier taste and slightly higher microbial counts than the control sample. The mozzarella samples differed slightly in colour and texture as well. The overall quality changes suggested that the use of the studied mesophilic lactobacilli as governing liquid additives may not be appropriate for high-moisture mozzarella cheese preservation.

Development of an innovative phytosterol derivatization method to improve the HPLC-DAD analysis and the ESI-MS detection of plant sterols/stanols.

HPLC analyses of phytosterols are associated with the issues of sensitivity due to their high lipophilicity and their lack of chromophore. These problems could be solved through chemical modifications of plant sterols/stanols structures. Therefore, the present study aims to develop a new method for phytosterols derivatization. This method was performed using dansyl chloride (4 mg ml-1) as derivatizing agent and different reaction parameters have been optimized. The highest yields of phytosterol derivatization were obtained with 4-dimethylaminopyridine (DMAP) as catalyst at a concentration of 8 mg ml-1 and dichloromethane as reaction solvent. In addition, 40 ˚C was the best reaction temperature for 30 min as the best reaction time. This derivatization method presented a high reproducibility (%RSD = 1.2-2.7%) and a good linearity (R2 = 0.9982-0.9999). The UV absorption intensities after derivatization showed a 23-fold increment for plant sterols and a 400-fold increment for plant stanols. Moreover, this derivatization method allowed the use of high and more selective wavelengths of detection and improved the chromatographic separation of phytosterols. Furthermore, the developed method allowed the ESI-MS ionization and analysis of phytosterols. This method can therefore contribute to the improvement of the HPLC analyses of plant sterols/stanols.