Lecithin Improves Texture of Reduced Fat Cheeses

Cheddar-type cheeses with 33% fat reduction were made with 0.2 or 0.5% (w/w) lecithin. Reduced fat cheeses with no lecithin and full fat cheeses were prepared as controls. Cheeses were aged 3 mo prior to instrumental and sensory evaluation. Reduced fat cheese with lecithin received higher overall texture scores from dairy judges than reduced fat control cheeses (P ≤ 0.05). Texture scores from dairy judges for cheeses with lecithin were not different from full fat cheeses. Reduced fat cheeses with lecithin were softer than reduced fat control cheeses as measured instrumentally and according to specific attribute panelists (P ≤ 0.05). Cheese wet weight yields were greater with addition of lecithin (P ≤ 0.05) which resulted in a softer more desirable texture in reduced fat cheeses.     

Fat Mimetics in Low-Fat Cheddar Cheese

Cheeses with 60% reduced fat content were prepared with three commercial fat mimetics. Low-fat cheeses without added fat mimetics and full-fat cheeses were prepared as controls. Cheeses were aged 3 months prior to sensory and instrumental evaluation. A low-fat cheese containing one of the fat mimetics received the highest texture scores from dairy judges and consumer panelists (P≤0.05). The low-fat control and another cheese with a fat mimetic received higher flavor scores from the trained dairy judges and consumer panelists than the other cheeses containing fat mimetics (P≤0.05). Low-fat cheeses containing fat mimetics were less rubbery than the low-fat control cheese (P≤0.05).     

Sensory Evaluation of Reduced Fat Cheeses

The objectives of this research were to compare the effects of seven make-procedures on the sensory quality of reduced fat Monterey Jacktype cheeses. Modifications (decreased cook temperature, decreased ripe time, decreased starter, homogenization, added milk-solids-not-fat, added flavor cultures, and washed curd) were incorporated into standard make-procedures for 33% reduced fat (RF) Monterey Jack-type cheeses. Two controls, a standard full fat cheese, and a standard RF cheese, were also prepared. Cheeses were aged 3 and 7 mo prior to sensory evaluation. The full fat control cheese and the washed curd RF cheese received the highest flavor scores from trained dairy judges (n = 9) and the highest flavor and acceptance scores from a consumer panel (n = 125). Washed curd was an effective modification for optimum sensory quality of RF cheeses.     

Milkfat Sucrose Polyesters as Fat Substitutes in Cheddar-type Cheeses

Milkfat sucrose polyesters (SPE) were substituted for 10, 25, 50, or 75% (w/w) of mllkfat in reconstituted milk and made into Cheddar-type cheeses. Total fat, moisture, and salt contents of the cheeses averaged 27, 49, and 1.2% (w/w). respectively. A screened sensory panel (n=22) determined that cheeses containing SPE were significantly different from the control cheese. Colorlmetrlc measurements of the total difference (ΔE) of the cheeses containing SPE from the control cheese increased as % SPE in the cheese increased (r=0.90). Firmness of the cheeses did not differ (p<0.05). Cheddar-type cheeses made with mllkfat SPE substituted for milkfat may have potential marketability.     

Casein Peptization, Functional Properties, and Sensory Acceptance of Processed Cheese Spreads Made with Different Emulsifying Salts

ABSTRACT:  " Requeijão cremoso " is a traditional Brazilian processed cheese spread, showing ample acceptance on the national market. Emulsifying salts (ES) are an important factor influencing the characteristics of processed cheeses, but the literature presents conflicting results about their action on cheese functionality.  Requeijão cremoso  obtained from anhydrous ingredients allows the study of the influence of each type of ES on the cheese properties, since it can be treated as a model system where the variables are limited and well known. The objective of this study was to evaluate the effect of different types of ES (TSC—sodium citrate, SHMP—sodium hexametaphosphate, STPP—sodium tripolyphosphate, and TSPP—tetrasodium pyrophosphate) on the sensory and functional characteristics of  requeijão cremoso -processed cheeses obtained from anhydrous ingredients. The physicochemical composition, degree of casein dissociation, fat particle size, melting index, color, texture profile, and sensory acceptance of the cheeses were determined. The functional behavior of processed cheeses was strongly influenced by the type of ES and its physicochemical properties including its ability to bind Ca, the casein dispersion during cooking, and the possible creation of cross-links with casein during cooling. The cheese made with SHMP was the one most differentiated from the others, presenting lower melting index, whiter color, and higher values for hardness, gumminess, and adhesiveness. The differences in texture had an impact on sensory acceptance: with the exception of the sample manufactured with sodium hexametaphosphate, all the samples presented good sensory acceptance.     

Composition and Quality Attributes of Reduced-Fat Cheese as Affected by Lecithin Type

Cheddar cheeses with 33% reduced-fat content were prepared with granular soy lecithin, hydrogenated soy lecithin, or oat. Addition of lecithin increased the wet weight yields and moisture of cheeses (P≤0.05). Reflected color values (L* and h_ab) were increased in cheeses containing granular soy lecithin (P≤0.05). Acid values of cheeses with lecithin were higher than control cheeses (P≤0.05). Concentrations of lecithin at 0.2% (w/w) resulted in visible changes in micro-structure of the cheeses. Granular soy lecithin or oat lecithin added to reduced-fat cheeses resulted in a decrease in flavor quality (P≤0.05). Hydrogenated soy lecithin added to reduced-fat cheeses improved texture quality without negatively affecting flavor quality.     

Improvement of sensory quality of lowfat kefalograviera-type cheese by using commercial special starter cultures

Two commercially available special starter culture systems, Alp DIP and a mixture of Alp DIP D and Joghurt V1, were compared with one commercial regular starter culture, CH-1, for their effects on the compositional, sensory and textural characteristics of lowfat (9.5%) high moisture (49.6%) Kefalograviera-type cheese during aging. A full-fat control Kefalograviera cheese (30.8% fat, 37.8% moisture) was also made with the regular starter culture. The results indicated that the type of starter did not affect the composition (moisture, fat, protein, salt and pH) of the lowfat cheese. Sensory analysis showed that the lowfat cheeses made with the special cultures received greater body and texture scores and significantly higher flavor scores than the lowfat control cheese after aging for 90 and 180 d. Moreover, the former cheeses received body and texture and flavor scores not significantly different from those of the full-fat cheese. Texture profile analysis by Instron showed that there were no significant differences in the textural characteristics (force and compression to fracture, cohesiveness, springiness, gumminess and chewiness) between lowfat cheeses made with the special cultures and that made with the regular starter, except for hardness which was significantly lower in the former cheeses.     

The effect of adding enzyme‐modified cheese on sensory and texture properties of low‐ and high‐fat cream cheeses

The influence of enzyme‐modified cheese (EMC) and fat content on sensory and texture properties of cream cheese was investigated. Enzyme‐modified cheese and fat content were set at three levels each, and organoleptic and texture properties for all experimental cheeses were then determined. Data were analysed using response surface methodology. Both design parameters had significant influence on sensory and texture properties. The EMC did not alter hardness significantly, whereas the higher fat formula had the higher hardness. The results indicated that the optimum level of EMC was less than 1% for high‐fat cream cheeses and at least 5% for low‐fat cream cheeses.     

Effect of iron fortification on microstructural,textural, and sensory characteristics of caprine milk Cheddar cheeses under different storage treatments

In this study, we manufactured 3 types of caprine milk Cheddar cheese: a control cheese (unfortified) and 2 iron-fortified cheeses, one of which used regular ferrous sulfate (RFS) and the other used large microencapsulated ferrous sulfate (LMFS). We then compared the iron recovery rates and the microstructural, textural, and sensory properties of the 3 cheeses under different storage conditions (temperature and duration). Compositional analysis included fat, protein, ash, and moisture contents. The RFS (FeSO₄·7H₂O) and LMFS (with 700- to 800-μm large particle ferrous sulfate encapsulated in nonhydrogenated vegetable fat) were added to cheese curds after whey draining and were thoroughly mixed before hooping and pressing the cheese. Three batches of each type of goat cheese were stored at 2 temperatures (4°C and ?18°C) for 0, 2, and 4 mo. We analyzed the microstructure of cheese using scanning electron microscopy and image analysis software. A sensory panel (n = 8) evaluated flavors and overall acceptability of cheeses using a 10-point intensity score. Results showed that the control, RFS, and LMFS cheeses contained 0.0162, 0.822, and 0.932 mg of Fe/g of cheese, respectively, with substantially higher iron levels in both fortified cheeses. The iron recovery rates of RFS and LMFS were 71.9 and 73.5%, respectively. Protein, fat, and ash contents (%) of RFS and LMFS cheeses were higher than those of the control. Scanning electron microscopy analyses revealed that LMFS cheese contained smaller and more elongated sharp-edged iron particles, whereas RFS cheese had larger-perimeter rectangular iron crystals. Iron-fortified cheeses generally had higher hardness and gumminess scores than the control cheese. The higher hardness in iron-fortified cheeses compared with the control may be attributed to proteolysis of the protein matrix and its binding with iron crystals during storage. Control cheese had higher sensory scores than the 2 iron-fortified cheeses, and LMFS cheese had the lowest scores for all tested sensory properties.     

Reduced fat process cheese made from young reduced fat Cheddar cheese manufactured with exopolysaccharide-producing cultures

In a previous study, exopolysaccharide (EPS)-producing cultures improved textural and functional properties of reduced fat Cheddar cheese. Because base cheese has an impact on the characteristics of process cheese, we hypothesized that the use of EPS-producing cultures in making base reduced fat Cheddar cheese (BRFCC) would allow utilization of more young cheeses in making reduced fat process cheese. The objective of this study was to evaluate characteristics of reduced fat process cheese made from young BRFCC containing EPS as compared with those in cheese made from a 50/50 blend of young and aged EPS-negative cheeses. Reduced fat process cheeses were manufactured using young (2 d) or 1-mo-old EPS-positive or negative BRFCC. Moisture and fat of reduced fat process cheese were standardized to 49 and 21%, respectively. Enzyme modified cheese was incorporated to provide flavor of aged cheese. Exopolysaccharide-positive reduced fat process cheese was softer, less chewy and gummy, and exhibited lower viscoelastic moduli than the EPS-negative cheeses. The hardness, chewiness, and viscoelastic moduli were lower in reduced fat process cheeses made from 1-mo-old BRFCC than in the corresponding cheeses made from 2-d-old BRFCC. This could be because of more extensive proteolysis and lower pH in the former cheeses. Sensory scores for texture of EPS-positive reduced fat process cheeses were higher than those of the EPS-negative cheeses. Panelists did not detect differences in flavor between cheeses made with enzyme modified cheese and aged cheese. No correlations were found between the physical and melting properties of base cheese and process cheese.     

Improvement of texture and structure of reduced-fat Cheddar cheese by exopolysaccharide-producing lactococci

The objective of this study was to evaluate the effect of capsular and ropy exopolysaccharide (EPS)-producing strains of Lactococcus lactis ssp. cremoris on textural and microstructural attributes during ripening of 50%-reduced-fat Cheddar cheese. Cheeses were manufactured with added capsule- or ropy-forming strains individually or in combination. For comparison, reduced-fat cheese with or without lecithin added at 0.2% (wt/vol) to cheese milk and full-fat cheeses were made using EPS-nonproducing starter, and all cheeses were ripened at 7°C for 6 mo. Exopolysaccharide-producing strains increased cheese moisture retention by 3.6 to 4.8% and cheese yield by 0.28 to 1.19 kg/100 kg compared with control cheese, whereas lecithin-containing cheese retained 1.4% higher moisture and had 0.37 kg/100 kg higher yield over the control cheese. Texture profile analyses for 0-d-old cheeses revealed that cheeses with EPS-producing strains had less firm, springy, and cohesive texture but were more brittle than control cheeses. However, these effects became less pronounced after 6 mo of ripening. Using transmission electron microscopy, fresh and aged cheeses with added EPS-producing strains showed a less compact protein matrix through which larger whey pockets were dispersed compared with control cheese. The numerical analysis of transmission electron microscopy images showed that the area in the cheese matrix occupied by protein was smaller in cheeses with added EPS-producing strains than in control cheese. On the other hand, lecithin had little impact on both cheese texture and microstructure; after 6 mo, cheese containing lecithin showed a texture profile very close to that of control reduced-fat cheese. The protein-occupied area in the cheese matrix did not appear to be significantly affected by lecithin addition. Exopolysaccharide-producing strains could contribute to the modification of cheese texture and microstructure and thus modify the functional properties of reduced-fat Cheddar cheese.     

Rheology of Full-fat and Low-fat Cheddar Cheeses as Related to Type of Fat Mimetic

Cheeses with 60% reduced fat were prepared with three fat mimetics and viscoelasticity was studied. Storage and loss moduli of low-fat cheeses made with a carbohydrate-based fat mimetic were greater (p < 0.05) than those of low-fat cheeses made with two protein-based fat mimetics or low-fat control cheese, but smaller (p < 0.05) than the storage and loss moduli of full-fat cheese. A six-element Kelvin model properly predicted the creep compliance for the full-fat cheese and the low-fat cheeses made with or without fat mimetics. Low-fat cheese made with a carbohydrate-based fat mimetic had a network structure more similar to full-fat cheese than the low-fat control or samples made with protein-based fat mimetics.     

Accelerated ripening of low fat Ras cheese by attenuated lactobacilli cells

Thirteen Ras cheese were made from 4% fat raw milk; 3% raw and heat treated; 2% raw and heat treated milks in order to study the effect of freeze-shocked or heat-shocked L. casei NIH 334 or L. helveticus CNRZ 53 on the quality of the resultant cheeses. The soluble nitrogen, soluble tyrosine, soluble tryptophan, total volatile fatty acids, titratable acidity and organoleptic evaluation scores increased as ripening period progressed, while moisture decreased. Neither strain nor the heated lactobacilli had significant effects on moisture content of cheeses, while increasing their acidity. Cheeses with freeze-shocked L. casei or L. helveticus had higher titratable acidity than cheeses in which heat-shocked cells were added. However, cheeses added L. helveticus had higher acidity than those with L. casei. Ripening indices (soluble nitrogen, soluble tyrosine, soluble tryptophan and total volatile fatty acids) and organoleptic evaluation scores had similar trends. Cheeses with attenuated lactobacilli had higher ripening indices and cheese scores than cheeses without lactobacilli. Addition of either freeze-shocked L. casei or L. helveticus yielded cheeses having higher ripening indices and organoleptic scores than cheeses made with heat-shocked lactobacilli. The best cheeses were made from 3% fat milk heated to 70 °C, and containing freeze-shocked L. helveticus followed by cheeses made from 2% fat milk heated to 75 °C and containing freeze-shocked L. helveticus.     

Effect of inulin addition on the sensorial properties of reduced‐fat fresh cheese

A reduced‐fat fresh cow's milk cheese with inulin (3%) was compared with both full‐fat and reduced‐fat cheeses without the prebiotic. The pH and microbiological quality of cheeses were not affected by the presence of inulin. Cheeses produced with inulin were less hard, springy, cohesive and chewy than reduced‐fat cheeses, and more similar to cheeses made from whole milk. Cheeses produced with inulin had the lowest lightness and the highest yellowness values, although these colour differences were not detected by the panellists. The sensory panel described the reduced‐fat cheese with inulin as more acceptable than its counterpart without inulin.