CIENCIAS DE LOS ALIMENTOS: FOOD SCIENCE

 

Sucralose-mediated effect during post-harvest of summer squash (Cucurbita pepo L.) cv. Ambassador from organic cultivation, using both systems active and passive modified atmosphere

Efecto de la adición de sucralosa en post cosecha en zapallos orgánicos (Cucurbita pepo L.) cv. Ambassador utilizando atmósfera modificada activa y pasiva

 

Loyola, N. a*, Acuña, C. a, Arriola, M. a, Velásquez, A. a

a Departamento de Ciencias Agrarias, Facultad de Ciencias Agrarias y Forestales, Universidad Católica del Maule, Carmen 684, Curicó, Chile.
* Corresponding author: Nelson Loyola. E-mail address: nloyola@ucm.cl


ABSTRACT

The objectives of this study were to evaluate the behavior of the use of sucralose to 1% in post-harvest fruits of summer squash (Cucurbita pepo L.), cv. Ambassador organically grown and stored under active and passive modified atmosphere (AMA and PMA), from two different pre-harvest conditions, with mulch and without mulch on the incidence in sensory evaluation of attributes. Each trial consisted of 3 treatments: T0 corresponding to the control, packaging under normal atmosphere, T1 packaged in AMA (20% of CO2 injection and 80% N) + sucralose 1% and T2 packaging for PMA + sucralose 1% without injection of gas, the fruits being evaluated in the measurement of gases at 12 and 25 days of refrigerated storage. As for the sensory analysis there was a negative effect of sucralose, being better evaluated treatment T0. Appearance results do not match those of acceptability, but still the treatment of active modified atmosphere (T1) was better than that evaluated with passive modified atmosphere (T2), indicating that the active modified atmosphere may help maintain the appearance of fruit and thus a better acceptability. Therefore, according to the results there was no positive effect of sucralose in the preservation of sensory attributes of summer squash.

Keywords: Cucurbita pepo L., sucralose, modified atmosphere, sensory evaluation


RESUMEN

Los objetivos del presente estudio fueron evaluar el comportamiento de frutos de zapallos italianos (Cucurbita pepo L.) cv. Ambassador, cultivados de forma orgánica almacenados en modificación de atmósfera MAP y SAP y con la adición de sucralosa al 1% en postcosecha, provenientes de dos diferentes condiciones de cultivo; con y sin mulch y su incidencia en atributos de evaluación sensorial. Cada ensayo consistió de 3 tratamientos: T0 correspondiente al control, almacenamiento bajo atmósfera normal, T1 envasado en MAP (inyección 20% de CO2 y 80% de N) + sucralosa 1% y T2 correspondiente a envasado en SAP + sucralosa 1% sin inyección de gases, siendo evaluados los atributos sensoriales de los frutos y el contenido de gases de los envases a los 12 y 25 días de almacenamiento refrigerado. Los resultados de la apariencia de los frutos por los panelistas no fueron diferentes a la aceptabilidad, pero la fruta con el tratamiento de atmósfera modificada active (T1) fue mejor evaluada que aquella con modificación pasiva de atmósfera (T2), indicando que la modificación de atmósfera activa puede ayudar a mantener la apariencia de los frutos y con una mejor aceptabilidad. Sin embargo, por lo estudiado, no existió un efecto positivo de la sucralosa en la conservación de los atributos sensoriales del zapallo italiano.

Palabras clave: Cucurbita pepo L., sucralosa, modificación de atmosfera, evaluación sensorial.


 

INTRODUCTION

The planted area with summer squash (Cucurbita pepo L.) in south-central Chile, according to the Census of Agriculture and Forestry VII (2007), is 996.3 ha, found mainly in the Metropolitan Region, Valparaiso Region V, and Maule Region VII. Despite being produced throughout the year, both in greenhouses and in the open air, it is a crop of middle importance with most of the production going to supply the domestic market, mainly from October to April (ODEPA, 2010).

The "mulch" or padding is a technique practiced for many years by farmers and involves placing a material on the ground to form a deck, in order to protect the crops and the soil itself from weather erosion and water evaporation. This layer also prevents certain crops from being frozen or damaged by contact with the ground (Escobar, 1990). Sucralose can also be used to improve the condition of maturity of fruits, by covering the fruit with a layer that complements the cold storage and thus extends the post-harvest life. Its principle of operation is based on the restriction of the permeability of fruits to those gases involved in the maturity process, acting as a modified atmosphere. Both techniques may contribute to diminish the loss of water in the growing fruits, as well as to maintain the fresh squash quality.

The present study was based on the following hypothesis: The application of 1% sucralose (C12H19CI3O8) and the use of modified atmosphere in post-harvest evaluation might improve the sensory perception of summer squash cv. Ambassador, organically grown, with and without mulch. Therefore the aim of the study was to evaluate: 1) the use of sucralose in post-harvested summer squash cv. Ambassador, organically grown and stored under modified atmosphere AMA (active modified atmosphere) and PMA (passive modified atmosphere), 2) the carbon dioxide and oxygen concentration in bags with selective permeability containing summer squash cv. Ambassador, and 3) the sensory attributes on summer squash for fresh consumption, such as taste, color, aroma and texture, and acceptability.

MATERIALS AND METHODS

The test was conducted at the Universidad Católica del Maule, San Isidro's Campus, Los Niches, Curicó, Maule Region, Chile, at geographical location 35° 02' S, 71° 19' W (225 meters above sea level).

The climate in this area is lower temperate mesothermal stenothermic semiarid mediterranean. Temperatures range from a high in January of 27.5 °C and a minimum in July of 4.1 °C. The frost-free period is 219 days, with an average of 12 frosts a year, still relatively moderate. It registers 1,380 degree days annually and 1,472 hours of chill. Hydric regime has an annual average rainfall of 859 mm, a water deficit of 883 mm and a dry period of 7 months (Santibañez and Uribe, 1993).

The soil of San Isidro's campus, corresponds to the type of very fine sandy loam, Romeral series is alluvial, presents a flat topography and moderately rapid permeability and well drained (CIREN, 1997).

The fruit of summer squash (Cucurbita pepo L.) cv. Ambassador, which was established by direct seeding on the campus of the University, in an area of 660 m2 being distributed in four ridges of 110 m long and 90 cm wide. Of these, two implemented ridges were covered with black polyethylene based mulch. For subsequent measurements performed on post-harvest, summer squash cultivation was handled with an organic production system. Fruit harvesting was manually performed during the morning in February to avoid high temperatures. Summer squashes were harvested from the second cutting, being used according to their size, which works as a physiological maturity index, with a homogeneous size of 12 to 15 cm long and with an average weight of 110 g, particularly selecting healthy fruits, with no visible damage, being harvested in separate rows with and without mulch. SURFRUT provided the plastic boxes which had been previously identified.

Washing of the fruits was performed by dipping them for 2 minutes in 4 ppm of hypochlorite solution, waiting an additional 30 minutes to allow for sanitizing effect before drying with absorbent paper towel. There were two trials (A1 and A2), which corresponded to a trial with summer squashes organically grown with and without mulching, respectively.

There were three treatments: a control (T0), and two treatments (T1 and T2) for each of the tests, with three replicates:

Treatment T0: control treatment, with packing of fruit in a Styrofoam tray under normal atmosphere.

Treatment T1: AMA plus 1% Sucralose applied on the fruits. A bag, brand San Jorge FF Plum 604, was used. To this bag, a mixture of 20% CO2 and 80% N2 was applied by injection with a Tagler machine and then sealed using a pressure of 4 bar.

T2: PMA plus 1% Sucralose applied on the fruits. A bag, brand San Jorge FF Plum 604 was used. No application of gases was done and it was sealed with a Tagler machine using a pressure of 4 bar.

All treatments were applied equally to the summer squashes, obtained organically with and without mulch. Each package contained 3 summer squashes and the fruits for treatments T1 and T2 were immersed in a 1% solution of sucralose for a period of five minutes, and then allowed to drain. This process was applied equally to the summer squashes obtained from non-organical cultivation with and without mulch.

After applying the treatments, the squashes were stored in a cold chamber at an experimental temperature of 7 to 8 °C and 95% relative humidity for a period of 25 days. The bags of each treatment were placed in their respective container (RentaPack plastic boxes).

Two measurements were taken, at 12 and 25 days of storage, as specified in the flow chart (Figure 1).

 

Figure 1. Flow chart of the entire process of product application
and subsequent summer squash packaging
Figura 1.
Línea de flujo del proceso completo de elaboración y
subsecuente almacenamiento de zapallos.

 

Evaluations, both sensory and instrumental, of treatments T0, T1 and T2, for both assays, with and without mulch, consisted of three repetitions each, in which different parameters were measured at 12 and 25 days of refrigerated storage. The gas measurement was performed at the fruit company Copefrut, in Romeral, south-central Chile. A portable checkpoint (CO2/ O2) PBI sensor was used for determining contents of CO2 and O2 in percent for each treatment under AMA or PMA.

Using sensory evaluation guides, both structured and unstructured sensory analysis were performed, which included the participation of 14 trained panelists, who abstained from smoking, eating and drinking one hour before tasting. Furthermore, they also rinsed their mouth between the tasting of each sample, to avoid taste confusion. Panelists expressed their preference marking a cross on a 13 cm line of the unstructured guide, for the intensity of the attributes perceived: flavor, color, aroma and texture (Stone and Sidel, 1993). For evaluation of both appearance and acceptability, a structured-type guide with numeric scale from 1 to 9 was used, in which each panelist after his first impression had to answer how he liked or disliked the squashes typified under the different treatments (Wittig, 2001). A completely randomized design (C.R.D.) with factorial arrangement of 3 x 2 and a confidence level of 95% was used, considering the three factors: T0, T1 and T2 and two measurements at 15 and 25 days of refrigerated storage. For effects of multiple comparisons Tukey test was used, with a confidence level of 95%. The experimental unit contained three fruits in a bag with modified atmosphere.

RESULTS AND DISCUSSION

Oxygen Gas Measurements

Test A1

The percentage of O2 in container with squashes treated with active modified atmosphere (T1) and passive modified atmosphere (T2) with 1% sucralose application from a cultivation with mulch was compared and significant differences were observed (Figure 2).

 

Figure 2. Average oxygen percentage of summer squash (Cucurbita pepo L.) cv. Ambassador,
subjected to different post-harvest treatments, at 12 and 25 days of storage (A) with mulch
and (B) without mulch.
Figura 2. Porcentaje promedio de oxígeno de zapallos (Cucurbita pepo L.) cv. Ambassador
con mulch sometidos a diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento
(A) con mulch y (B) sin mulch.

 

For the post-harvest treatments, packages using passive modified atmosphere initially gave a higher percentage of O2 compared to canned squash. However, when considering the time spent in storage, a significant decrease in the percentage of O2 was observed in the packages. These results are consistent with another study that found that the modified atmosphere directly influenced the squashes, increasing respiratory rate and decreasing the percentage of O2 in containers similar to those used in this assay (Lucera et al., 2010). Chakraverty et al. (2003), claim that techniques related to post-harvest such as modified atmosphere could inhibit ethylene action to some degree by reducing respiration rate of the fruit.

Squashes are non-climacteric vegetables, therefore rate of respiration are not increased after harvest by response to ethylene biosynthesis. Because of this, it was found that the difference in the stock O2 was significant, this is likely because respiratory rate was significantly different at 12 and 25 days of storage (Chakraverty et al., 2003). Also, according to Chakraverty et al. (2003), it is important to consider that the respiratory rate of summer squashes is 17 to 18 mL CO2 kg-1 h-1 which is considered high, so that it could be estimated that both the active and passive modified atmospheres could help maintain the normal balance between CO2 and O2 through oxygen levels present in the containers.

Test A2

When comparing the percentage of O2 in the packages with squashes treated either with active or passive modified atmosphere, from cultivation without mulch, significant differences were observed (Figure 2). By observing the behavior of fruits without mulch, it could be said that the coincidences in terms of trends in the conditions of pre-harvest, mean that there was apparently an effect of active modified atmosphere on the balance of oxygen in the air inside the fruit container. This is a consequence of the lower O2 content present, since the percentage decreased between 12 and 25 days of storage, being lower than that for the squashes under passive modified atmosphere. Probably there was a lower respiratory activity with a subsequent decrease in oxygen consumption, which could translate in a lower degree of maturity of the fruit and therefore a better condition to be consumed as a fresh produce.

Lee et al. (1996), claim that the low density bags, as those used in this assay, are highly permeable to O2, which would explain why oxygen concentrations shown by the squashes with passive modified atmosphere treatment (T2) were higher than the contents of CO2. One method to reverse this situation involves choosing a container that includes an exchange of oxygen similar to the product respiration rate, so that an increase in temperature, would provoke an increase in respiration rate and permeability of the film in an equivalent amount (Mir and Beaudry, 2009).

Decreased oxygen levels may also have other effects on the fruit, as for example, inactivating the enzyme reactions to induce color changes of the surface of the fruits, by provoking a reduction of the amount of O2 in the package. The active modified atmosphere techniques can also reduce the discoloration of the fruit surface (Barry-Ryan et al., 2007).

CO2 gas measurement

Test A1

The squash treated with active modified atmosphere plus 1% sucralose (T1) and passive modified atmosphere plus 1% sucralose (T2), both at 12 and 25 days of storage, showed significant differences in the percentage of CO2 (Figure 3). The squashes stored in active modified atmosphere (T1) had higher percentages of CO2 compared to those treated with passive modified atmosphere (T2), being probably lessened the respiratory rate in the first due to increased CO2 levels during storage (Kader, 2002).

 

Figure 3. Percentage of average carbon dioxide in summer squash (Cucurbita pepo L.) cv.
Ambassador, subjected to different post-harvest treatments, at 12 and 25 days of storage
(A) with mulch and (B) without mulch.
Figura 3. Porcentaje promedio de dióxido de carbono de zapallos (Cucurbita pepo L.) cv.
Ambassador sin mulch sometidos a diferentes tratamientos de post cosecha a 12 y 25 días
de almacenamiento (A) con mulch y (B) sin mulch.

 

In analyzing the effect of storage time on post-harvest squashes, significant differences were observed, which were linked to a positive trend in the percentage of CO2 that increased by about 3 percentage points. The creation and maintenance of an optimum atmosphere inside the modified atmosphere packages would depend on the product respiratory rate and the film permeability to CO2, which is affected by temperature (Kader, 2002).

Lucera et al. (2010), in an essay with different types of active and passive modified atmosphere packaging, reported that there was an effect mediated by the active modified atmosphere and the packaging type used in post-harvest, specially regarding the percentage of CO2. These authors obtained similar values to those presented here using a container made of organic polymers.

Test A2

When comparing the percentage of CO2 in the packages of squashes from a crop without mulch as a condition of pre-harvest and post-harvest treatments (T1 and T2), a significant difference was obtained (Figure 3).

If only post-harvest treatments are analyzed, squashes that exhibited higher percentages of CO2 in the package, were those treated with active modified atmosphere plus 1% sucralose (T1), coinciding in their tendency with the pre-harvest use of mulch.

In analyzing the effect of storage time on the content of CO2 in squash package, an increase of nearly 3% was observed after 25 days storage, coinciding with what happened when using mulch as pre-harvest cover.

Sensorial analysis

Acceptability assays A1 and A2

Comparing summer squashes subjected to various post-harvest treatments for the entire storage period, significant differences in acceptability were found for both cases of squash cultivated with and without mulch (Figure 4). In analysis of post-harvest treatments for both assays, with and without mulch, a similar trend was observed; panelists evaluated the fruits from the control treatment (T0) with the highest score, with a result closet score 7.

 

Figure 4. Acceptability average of summer squash (Cucurbita pepo L.) cv. Ambassador,
subjected to different post-harvest treatments, at 12 and 25 days of storage. Figure
A: Fruits from a culture with mulch. B: Fruits from a culture without mulch.
Figura 4. Aceptabilidad promedio de zapallos (Cucurbita pepo L.) cv. Ambassador, sometidos
a diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento. Figura
A: Frutos cultivados con mulch. B: Frutos cultivados sin mulch.

 

Squashes treated with active modified atmosphere plus 1% sucralose (T1) were evaluated with a score 6. The fruits with lowest evaluation (score 4) were those treated with passive modified atmosphere plus 1% sucralose (T2). Paliyath et al., (2008), state that the acceptability is not a factor that is determined by the conditions of post-harvest, but is a factor essentially genotypic specific to the species being treated and is also closely related to the amount of organic acids and sugars present in the fruit, so that the acceptability may be related to the soluble solids and pH.

Lucera et al. (2010), corroborate the results obtained in this experiment. They stated that the active modified atmosphere treatments (T1) could help keeping summer squash acceptability, better than the passive modified atmosphere treatments (T2).

By comparing the evolution of the values of acceptability in time, no significant differences in both trials were observed, although there was a small decline in the acceptability from 12 to 25 days of refrigerated storage. These results were also observed by Lucera et al. (2010), in a study involving squashes, noting a decrease in acceptability with storage time.

By examining the results of the sensorial analysis, there was probably a negative effect of sucralose on the acceptability of the fruits (T1 and T2), because the squashes under treatment with sucralose showed lower acceptability than those under the control treatment (T0).

Appearance tests, A1 and A2

Appearance is used along the production chain as the primary means of judging the quality of individual units of product. Product appearance is characterized mainly by absence of defects, size, shape and color (Kays, 1997).

When comparing the appearance of squashes from different post-harvest treatments (T0, T1 and T2), after 25 days of refrigerated storage, significant differences were found, particularly in the trial with fruits from a cultivation with mulch (Figure 5).

 

Figure 5. Average appearance of summer squash (Cucurbita pepo L.) cv. Ambassador,
subjected to different post-harvest treatments, at 12 and 25 days of storage. Figure
A: Fruits from a culture with mulch. B: Fruits from a culture without mulch.
Figura 5. Apariencia promedio de zapallos (Cucurbita pepo L.) cv. Ambassador, sometidos
a diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento. Figura A:
Frutos cultivados con mulch. B: Frutos cultivados sin mulch.

 

For all post-harvest treatments, the squashes treated with active modified atmosphere plus 1% sucralose (T1) were the best evaluated with a score 7. The squash not subjected to any treatment (T0) were received a score of 6 from the 1-9 scale.

Squashes with least acceptance in terms of appearance were those where passive modified atmosphere plus 1% sucralose (T2) was applied. According to these results, no significant effect of sucralose on the appearance of the fruit was observed. At the same time, there was no clear response from the panelists regarding the treatment used and evaluated throughout storage.

In analyzing the appearance of the fruit during storage, it was observed that there were no significant differences in the responses of the panelists for either

of the two treatments, with values or scores of 7. According to Paliyath et al. (2008), the appearance of the plants should decline as a result of maturation, this did not happen in this study, where appearance remained constant, in the opinion of the panelists.

Appearance results did not match those of acceptability, but still the treatment of active modified atmosphere (T1) was better than that evaluated with passive modified atmosphere (T2), indicating that the active modified atmosphere may help maintaining the appearance of the fruit and thus a better acceptability.

Color assays, A1 and A2

Color of squash from cultivation with mulch from the different post-harvest treatments (T0, T1 and T2) showed no significant differences throughout the storage period. However, significant differences in color were found for those squashes in cultivation without mulch (Figure 6).

 

Figure 6. Average color of summer squash (Cucurbita pepo L.) cv. Ambassador, treated
with different post-harvest treatments, at 12 and 25 days of storage. Figure A: Fruits
from a culture with mulch. B: Fruits from a culture without mulch.
Figura 6. Color promedio de zapallos (Cucurbita pepo L.) cv. Ambassador, sometidos a
diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento. Figura A:
Frutos cultivados con mulch. B: Frutos cultivados sin mulch.

 

Fruits from cultivation without mulch, subjected to the three treatments (T0, T1 and T2) and subsequent cooking, and presented for sensorial analysis in the form of slices, did not show significant differences in the green color of their skin and pulp. After 25 days of storage, darker shades of skin and flesh were observed (and fruits of treatments T0, T1 and T2 received a score of 6 points on a scale of 1-13.

Comparing the results of sensorial analysis against those obtained for color by instrumental determination, as described previously, no significant correlation was found. Although darker shades in squashes receiving treatments (T1 and T2) were detected by sensorial analysis, as compared to those that did not undergo any post-harvest application (T0), the color parameter "b" of instrumental determination showed darker fruits only for treatment T2. On the contrary Lucera et al. (2010), reported that sensorial analysis revealed darker color in squashes treated with passive modified atmosphere over those treated with active modified atmosphere.

Olfactory assays, A1 and A2

Squashes from different post-harvest treatments (T0, T1 and T2), and different pre-harvest conditions, with and without mulch, were subjected to olfactory sensorial tests. In the fruits from pre-harvest condition with mulch, no significant differences in the responses were found, whereas in fruits from cultivation without mulch, significant differences were detected (Figure 7), yielding values close to strong aromas, for those fruits grown without mulch and values similar to soft aromas for those from assays with mulch.

 

Figure 7. Aroma average of summer squash (Cucurbita pepo L.) cv. Ambassador,
subjected to different post-harvest treatments, at 12 and 25 days of storage. Figure
A: squashes from a culture with mulch. B: squashes from a culture without mulch.
Figura 7. Aroma promedio de zapallos (Cucurbita pepo L.) cv. Ambassador, sometidos
a diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento. Figura
A: Frutos cultivados con mulch. B: Frutos cultivados sin mulch.

 

When comparing only the post-harvest treatments (T0, T1 and T2), the strongest flavors were detected in squash of control treatment (T0). The squashes with lower values for aroma were those to which the treatment of active modified atmosphere with added sucralose (T1) was applied. Furthermore, the application of a film with sucralose could reduce the respiration rate and prevented to some extent gas exchange from the fruit, thus decreasing the ripening process. This would lead to maintain the characteristic aroma of squash (Kader, 2002).

In assessing the performance of squashes during post-harvest storage, no significant difference was observed between 12 and 25 days of storage for both assays with and without mulch, since sensorial analysis resulted in a similar aroma perception in the fruits analyzed.

Texture assays, A1 and A2

Sensorial analysis of the squashes in all three treatments (T0, T1 and T2) and from cultivation with mulch, showed no significant differences in texture attribute. Significant differences in the response were found for fruits grown without mulch (Figure 8).

 

Figure 8. Average texture of summer squash (Cucurbita pepo L.) cv. Ambassador, subjected
to different post-harvest treatments, at 12 and 25 days of storage. Figure A: Fruits from a
culture with mulch. B: Fruits from a culture without mulch.
Figura 8. Textura promedio de zapallos (Cucurbita pepo L.) cv. Ambassador, sometidos a
diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento. Figura A: Frutos
cultivados con mulch. B: Frutos cultivados sin mulch.

 

Among the three treatments applied to the fruits, the control treatment (T0) received the best score for texture (score 6 on a 1-13 scale), indicating a rather crunchy texture. Therefore, squashes from passive modified atmosphere treatment plus 1% sucralose had higher texture values, compared to squashes from active modified atmosphere treatment plus 1% sucralose. Moreover, it was observed that the application of sucralose may improve texture, giving the fruits values closest to the crunchiness (score 4 on the 1-13 scale). Storage time caused a significant increase in the score value for the texture. From 12 to 25 days of storage score value for texture increased to values typical for a crispy product.

Flavor assays, A1 and A2

The squashes from the assays with mulch (A1), subjected to different postharvest treatments (T0, T1 and T2) did not show any significant difference in flavor, as compared to those from pre-harvest without mulch (A2), where significant differences in the taste of the fruit were observed (Figure 9).

 

Figure 9. Average flavour of summer squash (Cucurbita pepo L.) cv. Ambassador, subjected
to different post-harvest treatments, at 12 and 25 days of storage. Figure A: Fruits from a
culture with mulch. B: fruits from a culture without mulch.
Figura 9. Aroma promedio de zapallos (Cucurbita pepo L.) cv. Ambassador, sometidos a
diferentes tratamientos de post cosecha a 12 y 25 días de almacenamiento. Figura A:
Frutos cultivados con mulch. B: Frutos cultivados sin mulch.

 

Analyzing only the post-harvest treatments (T0, T1 and T2) for the assay without mulch, significant differences in flavor were observed, wherein squashes from the control treatments (T0) showed the highest values with respect to the attribute flavor. Intensity in flavor of the tested squashes diminished from treatments T1 to T2. Probably, sucralose had no effect on flavor attribute, since the fruits from the control treatments were those that obtained score values denoting a more intense flavor compared to the other two treatments. This may be because squashes underwent cooking for 1 minute, which probably allowed added sucralose to drain away from the fruit.

CONCLUSIONS

Treatments that best retained the level of gas in containers with treated squash, were those from treatment T1, with slight increase in percentage of CO2 and slight decrease in percentage of O2.

The results of sensorial analysis showed that sucralose had a negative effect on acceptability, appearance, color, flavor, aroma and texture, since treatments where sucralose was administered (T1 and T2) were rated with lower score values compared to the control treatment.

ACKNOWLEDGEMENT

Authors gratefully acknowledge financial support from project PTY-2007-168 funded by Fondo de Innovación Agraria (FIA) - Programa Territorial Integrado (PTI): "Alternativas de manejo para mejorar la vida post cosecha de frutas y hortalizas orgánicas para el mercado fresco de la VII región del Maule". The project was organized by SURFRUT Ltda., Avenida Ramón Freire 1390, Romeral, Curicó, in collaboration with the School of Agronomy of Universidad Católica del Maule.

 

REFERENCES

BARRY-RYAN, C., MARTIN-DIANA, A., RICO, D., BARAT, J. 2007. Extending and measuring the quality of fresh-cut fruit and vegetables: a review. Trends in Food Science & Technology 18(2): 373-386.

Centro de Información de Recursos Naturales (CIREN). 1997. Estudio Agrológico VII Región. Tomo II. Santiago.

CHAKRAVERTY, A., MUJUMDAR, A., RAGHAVAN, G., RAMASWAMY, H. 2003. Handbook of Postharvest Technology. Editions Marcel Dekker, Inc. 1st edition, New York.

ESCOBAR, B. 1990. Acolchamiento de suelos con filmes plásticos. Chile Hortofrutícola. Septiembre - Octubre. Volumen IV: 35-38.

KADER, A. 2002. Postharvest technology of horticultural crops. Third edition. California. Agriculture and Natural Resources, University of California, California.

KAYS, S. 1997. Postharvest physiology of perishable plant-product. Exon Press, Georgia.

LEE, L., ARUL, J., LENCKI R., CASTAIGNET, F. 1996. A review on modified atmosphere packaging and preservation of fresh fruits and vegetables: Physiological basis and practical aspects - Part II. Packaging Technology and Science 9: 1-17.

LUCERA, A., COSTA, C., MASTROMATTEO, M., CONTE A. DEL NOBILE M.A. 2010. Influence of different packaging systems on fresh-cut zucchini (Cucurbita pepo). Innovative Food Science and Emerging Technologies 11(2): 361-368.

MIR, N., BEAUDRY, R.M. 2009. Modified Atmosphere Packaging. Agroindustrial Research Service, USDA. Available at www.ba.ars.usda.gov/hb66/15map.pdf. Visited on December 4th 2011.

Oficina de Estudios y Políticas Agrarias (ODEPA). 2010. Boletín estadístico de hortalizas y tubérculos: superficie, precios y comercio exterior. Santiago.

PALIYATH, G., MURR, D., HANDA, A., LURIE, S. 2008. Postharvest Biology and Technology of Fruits, Vegetables, and Flowers. Wiley-Blackwell Publishing. New Delhi.

SANTIBAÑEZ, F., URIBE, J. 1993. Atlas Agroclimático de Chile. Regiones VI, VII y VIII. Facultad de Ciencias Agrarias y Forestales Universidad de Chile.

STONE, H., SIDEL, J. 1993. Sensory evaluation practiques. 2nd Edition. Academic Press, New York.

WITTIG, E. 2001. Evaluación sensorial: Una metodología actual para tecnología de alimentos. Facultad de Ciencias Químicas y farmacéuticas. Universidad de Chile, Santiago.

 


Received 14.07.14
Accepted 25.11.14