Alimentos

Artículo arbitrado

Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature

cheese models

Análisis del perfil de textura de queso Fresco y queso

Chihuahua utilizando modelos de queso miniatura

1

,2

1

NÉSTOR GUTIÉRREZ-MÉNDEZ , NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS

Recibido: Agosto 9, 2012

Aceptado: Febrero 27, 2013

Abstract

Resumen

In this study are described the protocols for the manufacture of

miniature version of Fresh and Chihuahua cheese. But also, it

was analyzed the usefulness of these miniature cheeses

determining instrumental Texture Profile Analysis (TPA). Portions

of 250g of pasteurized milk were used for the manufacture of

miniature Fresh-type and Chihuahua-type cheeses. The miniature

cheeses had 4 cm of diameter with a range weight of 28g

En este trabajo se expone la utilización de micro quesos,

elaborados bajo condiciones controladas de laboratorio, para

analizar el perfil de textura (TPA) en queso Fresco y queso

Chihuahua. La elaboración del queso Fresco y queso Chihuahua

en miniatura se realizó a partir de porciones de 250g de leche.

Una vez concluido el proceso de elaboración, se obtuvieron

quesos de 4 cm de diámetro con un peso de 28g (queso Fresco)

y 22g (queso Chihuahua). Los quesos miniatura tuvieron el

tamaño adecuado para realizar el TPA; se obtuvieron tres

muestras de cada queso miniatura. La composición de los mini-

quesos, así como las propiedades de textura fue similar a lo

observado en muestras comerciales de queso Fresco y queso

Chihuahua. Por lo que estos quesos miniatura pueden ser

utilizados para realizar una gran cantidad de pruebas evaluando

nuevos ingredientes y su efecto sobre la textura del queso

Fresco y del queso Chihuahua; ahorrando una cantidad

considerable de espacio, tiempo y dinero.

(Fresh cheese) to 22g (Chihuahua cheese). Miniature cheeses

had the proper size to perform TPA, obtaining three cheese

samples from each miniature cheese. The composition and texture

characteristics of miniature cheeses were similar than the

observed in commercial Fresh and Chihuahua cheeses. Miniature

cheeses can be used for the assessment of new ingredients

and their effect on the cheese texture, saving space, time and

costs.

Keywords: mini-cheeses protocol, cheese texture, Fresh

cheese, Chihuahua cheese.

Palabras clave: protocolo mini-quesos, textura del queso,

queso Fresco, queso Chihuahua.

Introduction

owadays, there is a growing interest in the development of new dairy products.Anumber

of new ingredients and technologies from around the world are helping to improve the

manufacture of cheese. Some examples of ingredients are the cheese-ripening enzymes,

N

lactic acid bacteria that produces exo-polisaccharides, acidulants (like sodium acid sulfate), anti-

caking agents and enzymes that improve the cheese yield.

_

1

________________________________

Universidad Autónoma de Chihuahua, Facultad de Ciencias Químicas. Circuito Universitario, Campus II. Chihuahua, Chih. México.

Dirección electrónica del autor de correspondencia: ngutierrez@uach.mx.

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Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

Recently, there also have been widely

explored new products for cheese added with

ingredients or modified to produce a benefit for

health. Some examples of these products are

the low-fat, and low-salt cheeses, and the

cheeses added with functional ingredients like

vitamins, minerals, probiotics, prebiotics, soluble

dietary fiber and omega-3 fatty acids (Pszczola,

results obtained with this probe give different

texture notes that have good correlation with the

obtained by sensory methods (Bourne, 1978;

Bourne, 2004). The instrumental TPA was

developed 40 years ago and it is a very popular

and used method not only in research but also

in the industry as quality control of the food

texture (Pons and Fiszman, 1996). Currently,

the instrumental TPA remains to be among the

most broadly used instrumental measurement

for cheese-texture evaluation (Gunasekaran and

Ak, 2003).

2006; Johnson et al., 2009). Nevertheless, one

of the main concerns in the use of new

ingredients or technologies for the manufacture

of cheese is the possible change in its texture

characteristics.

The assessment of new ingredients or

changes in the manufacture procedures over

the cheese texture usually requires the

production of experimental cheeses. Sometimes

due to the number of treatments and its

corresponding replicates the experiments use

to be, even on a pilot scale, expensive, time-

consuming, require large space for its storage,

and use to be of low reproducibility (Shakeel-

Ur-Rehman et al., 2001). Some alternatives for

the production of cheese on a pilot scale have

been suggested for different uses. Salles and

others (1995) reported a cheese model for

evaluation of sensory attributes and flavor

compounds. Milesi et al. (2007) reported the use

of mini soft cheeses for monitoring microbial

populations and proteolysis during the cheese

ripening. Shakeel-Ur-Rehman et al. (1998)

described the methodology for the manufacture

of miniature cheese with similar composition

and flavor of Cheddar cheese. This miniature

cheese has been used for the assessment of

the proteolytic activity and the heat resistance

of some lactic acid bacteria (Shakeel-Ur-

Rehman et al., 1999; Jeanson et al., 2003).

Hynes et al. (2000) modified the methodology

of Shakeel-Ur-Rehman et al. (1998) to produce

a miniature washed-curd cheese, under

controlled microbiological conditions. These

authors used this methodology for testing single

bacterial strains in a washed-curd cheese

environment. Nevertheless, almost all the

cheese models described have been used for

microbiology or sensory studies, but have been

scarcely used for texture analysis.

The cheese texture is influenced by the

ingredients used for its manufacture (composition

and heat treatment of the milk, lactic acid bacteria

used, type of coagulant, addition of gums, etc.),

the manufacturing procedures (acidification rate

of the milk and curd, cutting size, stirring and

stretching conditions of the curd, washing steps,

etc.), the chemical composition of the cheese

(

water, protein and fat content, pH, calcium,

sodium and phosphate content, etc.) and the

conditions of ageing (time and temperature,

residual enzyme activity, relative humidity, etc.)

(Lucey et al., 2003).

The texture, along with the flavor and

appearance of the food are the main factors in

the sensory acceptability of a food product

(Bourne, 2004). According to Bourne (2002) the

food texture is defined as …»that group of

physical characteristics that arise from the

structural elements of the food, are sensed

primarily by the tactile perception, are related to

the deformation, disintegration, and flow of the

food under a force, and are measured objectively

by functions of mass, time and distance»….

The texture in the food can be measured by

sensory tests like descriptive sensory analysis

with trained judges, and by using instrumental

methods (Bourne, 2004; Foegeding et al.,

2

011). One of the most used instrumental

methods for solid food is the Texture Profile

Analysis (TPA). In this method, a sample of food

is compressed and decompressed two times,

imitating the first two chews on a food. The

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• Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

In this study are described the protocols for

the manufacture of miniature version of two of

the most consumed cheeses in Mexico and USA

by the Hispanic community, the Fresh and

Chihuahua cheese. This miniature Fresh and

Chihuahua cheeses were compared in

composition and texture with commercial

samples of Fresh and Chihuahua cheese, to

assess its usefulness determining the texture

of these kinds of cheeses by instrumental TPA.

Lactococcus lactis spp. lactis, Lactococcus lactis

spp. cremoris and Lactococcus lactis spp. lactis

biovar diacetylactis (Choozit, Danisco, Niebüll,

Germany). The milk was incubated for one hour

at 32 ºC and afterward added with 100μL of CaCl₂

6.6 M and 13.75μL of chymosin, Chy-Max (Chr

Hansen, Horsholm, Denmark). After one hour of

incubation at 32 ºC, the coagulum was cut with a

3

stainless-steel spatula in small cubes of 0.8 cm ,

held for 10 minutes and then stirred at 150 rpm

for 60 minutes in an orbital shaker. The whey was

drained, and the curd was warmed to 38 ºC in a

water bath (IsoTemp 210, Fisher Sci, Iowa, USA)

until the pH reached 5.6. Then the curd was

salting with 1% NaCl (w/w) and transferred into

polypropylene tubes (4.3 cm diameter and 9 cm

height). The tubes were centrifuged at 1700 x g

for 30 minutes at room temperature. The expelled

whey was drained and the curd was centrifuged

again for 60 minutes at 1700 x g. Mini cheeses

were removed from the tubes, and stored in

refrigeration unpacked at 4 ºC and 75% Relative

Humidity (RH) for 48 hours. Finally, mini cheeses

were wiped with tissue paper, packed in hermetic

polyethylene bags (16.5 cm x 14.9 cm) and stored

at 3 °C for one week before its analysis (Figure 1).

Materials and Methods

Manufacture of miniature Fresh-type cheese.

Portions of 250g of standardized (3% fat)

milk were placed in four glass beakers of 500

mL and pasteurized at 63 °C for 30 minutes.

The milk portions were cooled at 32 °C and

added with 100μL of a CaCl solution 6.6 M.

2

Afterward, 13.75μL of chymosin (Chy-Max, Chr

Hansen, Horsholm, Denmark) was added to the

milk and incubated (incubator Shel Lab, Oregon,

USA) by one hour at 32 °C. The coagulum

formed was cut with a stainless-steel spatula

3

(

0.8 cm width) in small cubes of 0.8 cm , held

for 10 minutes and then stirred at 150 rpm for

0 minutes in an orbital shaker (DS-500, VWR,

6

Compositional Analysis

USA). The whey was drained, and the curd was

salting with 1% NaCl (w/w). The curd was

transferred into polypropylene tubes with flat

bottom (4.3 cm diameter and 9 cm height) and

centrifuged (Thermo IEC, Centra CL3R, USA)

at 1700 x g for 15 minutes at room temperature.

The whey expelled was drained and the curd

was centrifuged again at 1700 x g for 30 minutes.

After further whey drainage, mini cheeses were

removed from the tubes, wiped with tissue paper

and packed in hermetic polyethylene bags (16.5

cm x 14.9 cm). Mini cheeses were stored in

refrigeration at 3 °C for two days before its

analysis (see Figure 1).

Composition of the milk was determined with

an ultrasound analyzer MA250 (MilkTech, Miami,

USA). The pH was obtained by theAOAC method

981.12 (1998), placing the electrode of the pH

meter (Pinnacle, Corning, New York, USA) in

contact with the curd or grated cheese. Moisture

and protein content were determined by theAOAC

methods 926.08 and 991.22. The fat content was

determined by the Gerber method using a Roeder

butyrometer (Kirk et al., 2000).

Determination of instrumental Texture Profile

Analysis.

Texture properties were determined in Fresh-

type and Chihuahua-type miniature cheeses, as

well as in samples of commercial brands of

Chihuahua and Fresh cheese. Texture profile

analysis (TPA) was conducted using aTA.XTplus

Texture analyzer (Stable Micro System, London,

England). TPA was performed using a cylinder

Manufacture of miniature Chihuahua-type cheese.

Portions of 250 g of standardized (3% fat) milk

were placed in four glass beakers of 500 mL and

pasteurized at 63 °C for 30 minutes. Milk portions

were cooled at 32 °C and inoculated with a

freeze-dried starter culture that contained

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Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

Figure 1. General procedures for the manufacture of Fresh-type and Chihuahua-type miniature cheeses.

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• Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

flat-ended probe (P/2 SL) of 2.5 cm of diameter.

Three cylindrical sections (1.2 cm diameter and

moisture and neutral pH of the Fresh cheese allow

the growth of different microorganisms (even at

low temperatures) during its storage, acidifying

the pH of the cheese. The pH variability among

the samples of the different brands of Fresh

cheese and the miniature cheeses could be due

to differences in the time of manufacture before

its analysis. Nevertheless, in general, it was

observed that the composition of the different

Fresh cheese brands, and the miniature Fresh-

type cheeses were similar than the reported by

other authors (Table 1) for Fresh cheese

(VanHakken and Farkye, 2003).

1

.5 cm height) from each cheese sample (Figure

) were compressed by 75% twice using a

crosshead speed of 0.05 cm/sec. The second

compression was delayed 5 seconds from the

first compression. Cheese samples were allowed

to equilibrate at room temperature (25 ºC) prior

to testing. Hardness, fracturability, adhesiveness,

springiness and cohesiveness were calculated

by the software instrument called Texture

Exponent (Stable Micro System, London,

England).

Statistical analysis.

Miniature Chihuahua cheeses showed a

lower weight (22 ± 0.98g) and height (1.8 cm)

than the observed in the miniature Fresh

cheeses. The fat contents of the miniature

Chihuahua cheeses were the same that the

observed in the samples of the four brands of

Chihuahua cheese. The protein content of

miniature Chihuahua-type cheeses was equal to

three of the four commercial samples of

Chihuahua cheese. However, the moisture

content was significantly higher in the miniature

cheeses, and the second brand (Table 1) than

the observed in the other three brands of

Chihuahua cheese. Chihuahua cheese is a

semi-hard product made from either raw milk or

pasteurized milk by the Mennonite communities

settled in the state of Chihuahua, Mexico. The

main compositional difference between

Chihuahua cheese and Cheddar cheese is the

high moisture content, usually as high as 45%

(Gutierrez-Mendez and Nevarez-Moorillón, 2009).

The difference in moisture content among the

Chihuahua cheese brands assessed in this study

(Table 1) is probable due to differences in the

process methods or the ripening time of each

cheese. The miniature cheeses had only seven

days of ripening and thus, high moisture content,

whereas some brands of Chihuahua cheese use

to ripen the cheese at least one month. As well

as miniature Fresh cheeses, the miniature

Chihuahua cheeses had similar compositional

characteristics than the reported for Chihuahua

cheese brands (Gutierrez-Mendez and Nevarez-

Moorillón, 2009).

A completely randomized design was used

to compare rheological and proximal data

obtained from the mini cheeses with the

information acquired from samples of Fresh and

Chihuahua cheese brands.Additionally, aTukey

test was performed for multiple-comparison of

means. On the other hand, a principal

component analysis (PCA) using a correlation

matrix was carried out to determine similarities

or clusters among the cheese samples. PCA

was obtained with the data collected from the

TPA and compositional analysis. These

analyses were performed using the Minitab

Release 14.12.0 software (Minitab Inc. USA).

Results and Discussion

Composition of miniature cheeses.

Miniature Fresh cheeses had an average size

of 4 cm of diameter and 2.0 cm of height, with a

weight of 28 ± 1.04 g. The fat content of miniature

Fresh cheeses was the same that the observed

in the three brands of Fresh cheese. However,

their protein and moisture content was similar to

two of the three brands of Fresh cheese (Table

1). The pH of miniature Fresh cheeses and the

samples of the different Fresh cheese brands

were statistically different. Fresh cheese is a

curd-like product with high moisture (46-57%)

and low fat (18-29%) content and a nearly neutral

pH (6.1). The shelf life of this type of cheese is

only of two weeks in refrigeration (VanHekken and

Farkye, 2003; Walstra et al., 2006). The high

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Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

Table 1. Summary of the composition observed in commercial samples of Fresh and Chihuahua cheeses and miniature Fresh-type

and Chihuahua-type cheeses.

Fat

%)

Protein

(%)

Moisture

(%)

CHEESE TYPE

pH

(

Fresh-type miniature cheeses

Fresh cheese (Brand 1)

16.13 ± 1.93 ^a

18.25 ± 1.50 ^a

18.63 ± 1.11 ^a

16.50 ± 1.91 ^a

18-29

17.18 ± 2.57 ^b

19.24 ± 3.07 ^a^b

22.87 ± 1.19 ^a

15.72 ± 0.90 ^b

17-21

54.92 ± 1.01 ^a

50.60 ± 1.78 ^b

54.73 ± 0.66 ^a

55.63 ± 0.73 ^a

46-57

6.00 ± 0.02 ^b

5.91 ± 0.02 ^c

6.33 ± 0.06 ^a

5.84 ± 0.06 ^d

6.1

Fresh cheese (Brand 2)

Fresh cheese (Brand 3)

Fresh cheese*

Chihuahua-type miniature cheeses

Chihuahua cheese (Brand 1)

Chihuahua cheese (Brand 2)

Chihuahua cheese (Brand 3)

Chihuahua cheese (Brand 4)

27.25 ± 2.99 ^b

28.75 ± 2.22 ^a^b

30.75 ± 2.06 ^a

27.00 ± 2.16 ^b

27.00 ± 1.41 ^b

21-36

24.43 ± 1.42 ^a

25.97 ± 0.80 ^a

24.18 ± 2.21 ^a

20.42 ± 1.30 ^b

23.63 ± 0.61 ^a

22-28

42.3 ± 1.44 ^a

37.54 ± 1.43 ^b

43.34 ± 0.70 ^a

37.50 ± 0.73 ^b

38.74 ± 0.41 ^b

33-45

5.35 ± 0.05 ^c

5.43 ± 0.02 ^b

5.23 ± 0.01 ^d

5.48 ± 0.02 ^a

5.50 ± 0.01 ^a

5.0-5.5

Chihuahua cheese**

a,b,c,d,

Superscripts with different letter in the same column indicate significant differences (p < 0.05).

Composition of commercial Fresh cheeses reported by VanHekken and Farkye (2003).

*

*Composition of commercial Chihuahua cheeses reported by Gutierrez-Mendez and Nevarez-Moorillón (2009).

Texture profile of miniature cheeses.

(CCP) is undissolved. When the pH is lowered

the CCP dissolves, increasing salt bridges

between caseins and swelling; modifying the

texture properties of the cheese (Lucey et al.,

The fracturability (force observed at the first

significant break during the first compression

cycle) of miniature Fresh cheeses was equal to

the observed in all the commercial brands of

Fresh cheese (Table 2). Nevertheless, also

miniature Fresh cheeses were similar, at least

in two of the three brands of Fresh cheese, in

hardness (peak force during the first

compression), adhesiveness (work necessary

to pull the compressing plunger away from the

sample), springiness (the height that food

recovers), chewiness (work necessary for a

double compression) and cohesiveness

2003; VanHekken and Farkye, 2003).

The miniature Chihuahua cheeses

presented the same hardness and adhesiveness

than three of the four brands of Chihuahua

cheese analyzed (Table 2). The springiness of

the miniature cheeses was similar to the brands

four and one, but different to the brands two and

three. In contrast, the values of chewiness of the

miniature Chihuahua cheeses were similar to the

brands two and three but different to the brands

one and four. The Chihuahua cheese is

described as being a cross between Cheddar

and brick cheese, but some rheological

similarities to Colby and Havarti cheese have

been reported. Chihuahua cheese requires

similar force for fracture as fresh Cheddar

cheese, but tolerates deformation similar to

Colby cheese and has shear rigidity like Havarti

(Bourne, 1978). During the manufacture of Fresh

cheese, the curd is finely milled and salted,

producing a crumbly texture in the cheese

(VanHekken and Farkye, 2003). Because of this,

with a small load the cheese matrix can be

fractured. Fresh cheeses do not melt when

heated, because at the pH of this kind of cheese

(6.1) almost all the colloidal calcium phosphate

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• Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

and brick cheeses (Tunick et al., 2007; Van

Hekken et al., 2007; Tunick et al., 2008).

cheeses; probably, because its higher protein

content (Table 1) and acidic pH (6.3), but also

due to differences in its cohesiveness and

chewiness (Table 2). On the other hand,

miniature Chihuahua-type cheeses were similar

to Chihuahua cheeses of brand one, two and

three. However, Chihuahua cheeses of brand

four had different characteristics. The main

differences observed in the cheeses of brand

four were the high adhesiveness, and the low

values of chewiness and cohesiveness. These

results suggest that Chihuahua cheese of brand

four perhaps were added with an additional

ingredient like gum.

The texture of the cheese is produced by a

complex interaction of different factors like

cheese composition, manufacturing and

ripening conditions (Lucey et al., 2003). For this

reason, it is normal to observe coincidences and

differences between the commercial cheese

samples and the miniature cheeses.

Nevertheless, to know if miniature cheeses were

similar to their corresponding commercial

versions, it was performed a multivariate

analysis, considering all the responses of the

TPA and the compositional analysis. From the

PCA, the first principal component (PC1) had

an eigenvalue of 5.45, which explain 54.5% of

the total data variability. The second and third

principal components (PC2 and PC3) had

eigenvalues of 1.54 and 1.28. In Figure 2a, all

the cheese samples, including the commercial

Fresh and Chihuahua cheeses as well as the

miniature Fresh-type and Chihuahua-type

cheeses, were plotted using their scores from

the PCA. Miniature Fresh-type cheeses have

similar characteristics to the Fresh cheese of

brand one. The Fresh cheeses of brand two

were slightly different from the other Fresh

In Figure 2b, vectors represent a graphical

display of the loading for the variables used in

the PCA. The variables of cohesiveness,

hardness and chewiness had similar loads than

the variables of protein and fat content, indicating

that changes in fat and protein content will affect

these texture variables. This observation is

related to the described by Gunasekaran and

Ak (2003), that a reduction in fat content

produces an increase in the hardness of the

cheese. In contrast, the adhesiveness and

springiness showed similar loads that the pH

and the moisture.

Table 2. Texture profile analysis (TPA) of commercial Fresh cheese and Chihuahua cheese samples, and miniature Fresh-type and

Chihuahua-type cheeses.

Hardness

N)

Fracturability

(N)

Adhesiveness

(N.s)

Springiness

(mm)

Chewiness

(mJ)

CHEESE TYPE

Cohesiveness

(

Fresh-type miniature cheeses

Fresh cheese (Brand 1)

7.59 ± 0.59 ^a

6.84 ± 0.79 ^a

6.60 ± 0.51 ^a

4.50 ± 0.58 ^b

14.81 ± 2.55 ^a

23.84 ± 2.36 ^b

9.27 ± 0.96 ^a

11.76 ± 2.30 ^a

9.29 ± 2.00 ^a

2.54 ± 0.41 ^a

4.07 ± 3.53 ^a

1.99 ± 3.44 ^a

3.81 ± 0.58 ^a

5.48 ± 1.78 ^a

ND

0.20 ± 0.08 ^a

0.10 ± 0.02 ^a

0.03 ± 0.01 ^b

0.27 ± 0.02 ^a

0.26 ± 0.16 ^a

0.19 ± 0.26 ^a

0.18 ± 0.10 ^a

0.05 ± 0.07 ^a

0.67 ± 0.12 ^b

6.79 ± 0.80 ^a

7.61 ± 0.37 ^a

8.65 ± 0.44 ^b

6.76 ± 0.48 ^a

4.54 ± 1.25 ^a

6.71 ± 1.29 ^a^b

7.04 ± 0.49 ^b

8.05 ± 0.36 ^b

5.78 ± 0.50 ^a^b

9.98 ± 0.56 ^a^b

12.53 ± 1.83 ^b

22.62 ± 2.17 ^c

7.19 ± 1.43 ^a

34.69 ± 2.75 ^b

64.28 ± 2.48 ^c

27.14 ± 5.85 ^b

26.91 ± 7.93 ^a^b

13.09 ± 2.92 ^a

0.26 ± 0.04 ^a

0.24 ± 0.02 ^a

0.40 ± 0.02 ^b

0.23 ± 0.01 ^a

0.62 ± 0.02 ^d

0.38 ± 0.01 ^c

0.52 ± 0.02 ^b

0.28 ± 0.02 ^a

0.24 ± 0.02 ^a

Fresh cheese (Brand 2)

Fresh cheese (Brand 3)

Chihuahua-type miniature cheeses

Chihuahua cheese (Brand 1)

Chihuahua cheese (Brand 2)

Chihuahua cheese (Brand 3)

Chihuahua cheese (Brand 4)

ND

10.59 ± 3.26 ^a

6.39 ± 0.56 ^a

Mean value ± standard deviation; n=3. ND = not detected.

a,b,c,d

Superscripts with different letters in the same column, for the same type of cheese, indicate statistically significant differences (P<0.05).

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Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

Figure 2. (a) Principal component analysis obtained from the variables of composition and texture of Chihuahua cheeses, Fresh

cheeses and mini-cheese versions of Fresh and Chihuahua cheeses; (b) Graphical display of the loadings of the variables used

for the principal component analysis.

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• Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

JOHNSON, M. E., Kapoor, R., McMahon, D. J., McCoy, D. R., &

Conclusion

Norasimmon, R. G. 2009. Reduction of sodium and fat levels in

natural and processed cheese: scientific and technological

aspects. Comprehensive Reviews in Food Science and Food

The composition and texture characteristics

of the miniature cheeses were similar to the

obtained in the samples of commercial Fresh and

Chihuahua cheeses. For this reason, miniature

Fresh-type and Chihuahua-type cheeses could

be used for the assessment of texture or

changes in texture by addition or modification of

ingredients; saving space, time and costs.

Safety, 8, 250-268.

KIRK, R. S., Sawyer, R., & Egan, H. 2000. Composición y Análisis

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Cite this article as follows:

Gutiérrez-Méndez, N., N. Trancoso-Reyes y M. Yarely Leal-Ramos. 2013: Texture profile analysis of Fresh

cheese and Chihuahua cheese using miniature cheese models. TECNOCIENCIA Chihuahua 7(2): 65-74.

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Vol. VII, No. 2 • Mayo-Agosto 2013 •

NÉSTOR GUTIÉRREZ-MÉNDEZ, NALLELI TRANCOSO-REYES Y MARTHA YARELY LEAL-RAMOS: Texture profile analysis of Fresh cheese

and Chihuahua cheese using miniature cheese models

Resúmenes curriculares de autor y coautores

NÉSTOR GUTIÉRREZ MÉNDEZ. Ingeniero Agroindustrial por la Universidad Autónoma del Estado de Hidalgo (UAEH), con maestría en

Ciencia y Tecnología de Alimentos por la Universidad Autónoma de Chihuahua (UACH) y doctorado en Ciencia de los Alimentos por

el Centro de Investigación en Alimentación y Desarrollo (CIAD). Actualmente se desempeña como profesor investigador en la

Facultad de Ciencias Químicas de la Universidad Autónoma de Chihuahua. Participa en los programas de licenciatura y en el

posgrado en Ciencia y Tecnología de Alimentos. Ha sido ganador en dos ocasiones del Premio Nacional en Ciencia y Tecnología de

Alimentos. Actualmente miembro del Sistema Nacional de Investigadores Nivel I.

NALLELI TRANCOSO REYES. Terminó su licenciatura en 2009, año en que le fue otorgado el título de Ingeniero Bioquímico por el Instituto

Tecnológico de Durango (ITD). Realizó su posgrado en la Facultad de Ciencias químicas de la UniversidadAutónoma de Chihuahua,

donde obtuvo el grado de Maestro en Ciencias en el área de Tecnología de alimentos. Ha participado en 3 ponencias en congresos

y ha sido reconocida con el premio Nacional en Ciencia y Tecnología de Alimentos Coca-Cola 2011, en la categoría Profesional en

Tecnología de Alimentos.

MARTHA YARELY LEAL RAMOS. Terminó su licenciatura en 2001, año en que le fue otorgado el título de Ingeniero Químico opciónAlimentos

por la Facultad de Ciencias Químicas de la Universidad Autónoma de Chihuahua (UACH). Realizó su posgrado en Chihuahua,

México, donde obtuvo el grado de Maestro en Ciencias en Tecnología de Alimentos en 2005 por la Universidad Autónoma de

Chihuahua, y el grado de Doctor en Filosofía en el área de alimentos cárnicos en 2012 por la Universidad Autónoma de Chihuahua.

Desde 2010 labora en la Facultad de Ciencias Químicas de la UACH y posee la categoría de Académico titular B. Ha solicitado su

ingreso al Sistema Nacional de Investigadores en 2013. Su área de especialización es sobre tecnologías emergentes para el

procesamiento de alimentos, entre ellos la carne.

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• Vol. VII, No. 2 • Mayo-Agosto 2013 •