Quality evaluation of fresh-cut ‘Pérola’ pineapple stored in controlled atmosphere

Antoniolli, Lucimara Rogéria; Benedetti, Benedito Carlos; Sigrist, José Maria Monteiro; Silveira, Neliane Ferraz de Arruda

doi:10.1590/S0101-20612007000300017

Abstracts

The purpose of this research was to determine the best gas mixture in controlled atmosphere conditions to store fresh-cut ‘Pérola’ pineapple, particularly in relation to the maintenance of visual quality and reduction of microbial growth. After sanitation, fruit was manually peeled, sliced and dipped in 20 mg.L-1 NaOCl solution for 30 seconds. Then, the excess liquid was drained and the slices were placed in sealed glass jars connected to a flowboard installed in a cold room (5 ± 1 °C). Desired gas mixtures were supplied continuously for 12 days from cylinders connected to the flowboard. Controlled atmospheres of 2:5, 2:10, 2:15, 5:5, 5:10, 5:15, 8:5, 8:10 and 8:15 (O2:CO2, %) and air were used. The product was evaluated for pulp color, total and fecal coliforms, mesophilic and psychrotrophic aerobic, mold and yeast counts. Total and fecal coliforms were not detected. The fresh-cut ‘Pérola’ pineapple was not very sensitive to storage in controlled atmosphere, considering that the slices had little browning and were free of contamination, that would affect the food safety at the end of the storage period

Ananas comosus; minimal processing; gas mixture; quality; microbial growth

Procurou-se determinar a composição gasosa ótima para o armazenamento do abacaxi ‘Pérola’ minimamente processado, particularmente com relação à melhoria da qualidade visual e à redução do crescimento microbiano. Frutos previamente sanitizados foram descascados e fatiados manualmente. As fatias foram imersas em solução de NaOCl 20 mg.L-1 durante 30 segundos. Após período de repouso, para drenagem do excesso de líquido, foram acondicionadas em frascos de vidro herméticos conectados a um fluxcentro instalado em câmara refrigerada a 5 ± 1 °C. As composições gasosas desejadas foram fornecidas continuamente, durante 12 dias, a partir de cilindros conectados ao fluxcentro. As combinações de O2:CO2 (%), balanceadas com N2, foram as seguintes: 2:5, 2:10, 2:15, 5:5, 5:10, 5:15, 8:5, 8:10 e 8:15. O tratamento controle foi o ar atmosférico. Os parâmetros analisados foram: cor, coliformes a 35 e a 45 °C, microrganismos aeróbios mesófilos, psicrotrófilos, bolores e leveduras. Não foram detectados coliformes totais e fecais. A combinação 5:15 (O2:CO2, %) reduziu ligeiramente o crescimento microbiano, entretanto o abacaxi ‘Pérola’ minimamente processado parece ser pouco sensível ao armazenamento sob atmosfera controlada, considerando-se que ao término do armazenamento as fatias apresentavam-se pouco escurecidas e livres de contaminação que comprometesse a segurança do alimento.

Ananas comosus; processamento mínimo; composição gasosa; qualidade; crescimento microbiano

Quality evaluation of fresh-cut Pérola pineapple stored in controlled atmosphere

Avaliação da qualidade do abacaxi Pérola minimamente processado, armazenado sob atmosfera controlada

Lucimara Rogéria Antoniolli^I; Benedito Carlos Benedetti^II,^* * A quem a correspondência deve ser enviada ; José Maria Monteiro Sigrist^III; Neliane Ferraz de Arruda Silveira^III

^IEmbrapa Uva e Vinho, CP 130, CEP 95700-000, Bento Gonçalves - RS, Brasil

^IIFaculdade de Engenharia Agrícola FEAGRI, Universidade Estadual de Campinas UNICAMP, CP 6011, CEP 13083-875, Campinas - SP, Brasil, E-mail: benedeti@agr.unicamp.br,

^IIIInstituto de Tecnologia de Alimentos, CP 139, CEP 13073-001, Campinas - SP, Brasil

ABSTRACT

The purpose of this research was to determine the best gas mixture in controlled atmosphere conditions to store fresh-cut Pérola pineapple, particularly in relation to the maintenance of visual quality and reduction of microbial growth. After sanitation, fruit was manually peeled, sliced and dipped in 20 mg.L¹ NaOCl solution for 30 seconds. Then, the excess liquid was drained and the slices were placed in sealed glass jars connected to a flowboard installed in a cold room (5 ± 1 °C). Desired gas mixtures were supplied continuously for 12 days from cylinders connected to the flowboard. Controlled atmospheres of 2:5, 2:10, 2:15, 5:5, 5:10, 5:15, 8:5, 8:10 and 8:15 (O₂:CO₂, %) and air were used. The product was evaluated for pulp color, total and fecal coliforms, mesophilic and psychrotrophic aerobic, mold and yeast counts. Total and fecal coliforms were not detected. The fresh-cut Pérola pineapple was not very sensitive to storage in controlled atmosphere, considering that the slices had little browning and were free of contamination, that would affect the food safety at the end of the storage period.

Keywords:Ananas comosus; minimal processing; gas mixture; quality; microbial growth.

RESUMO

Procurou-se determinar a composição gasosa ótima para o armazenamento do abacaxi Pérola minimamente processado, particularmente com relação à melhoria da qualidade visual e à redução do crescimento microbiano. Frutos previamente sanitizados foram descascados e fatiados manualmente. As fatias foram imersas em solução de NaOCl 20 mg.L¹ durante 30 segundos. Após período de repouso, para drenagem do excesso de líquido, foram acondicionadas em frascos de vidro herméticos conectados a um fluxcentro instalado em câmara refrigerada a 5 ± 1 °C. As composições gasosas desejadas foram fornecidas continuamente, durante 12 dias, a partir de cilindros conectados ao fluxcentro. As combinações de O₂:CO₂ (%), balanceadas com N₂, foram as seguintes: 2:5, 2:10, 2:15, 5:5, 5:10, 5:15, 8:5, 8:10 e 8:15. O tratamento controle foi o ar atmosférico. Os parâmetros analisados foram: cor, coliformes a 35 e a 45 °C, microrganismos aeróbios mesófilos, psicrotrófilos, bolores e leveduras. Não foram detectados coliformes totais e fecais. A combinação 5:15 (O₂:CO₂, %) reduziu ligeiramente o crescimento microbiano, entretanto o abacaxi Pérola minimamente processado parece ser pouco sensível ao armazenamento sob atmosfera controlada, considerando-se que ao término do armazenamento as fatias apresentavam-se pouco escurecidas e livres de contaminação que comprometesse a segurança do alimento.

Palavras-chave:Ananas comosus; processamento mínimo; composição gasosa; qualidade; crescimento microbiano.

1 Introduction

Consumption of fresh-cut fruit and vegetables has been increasing because of their convenience and high quality. However, it is essential that these fresh-cut fruit and vegetables preserve the freshness and nutritional quality of the whole products, as well as being free of microbial contamination that would offer risks to the consumers^7,11. Fresh-cut pineapple can be found in some shops, but its shelf-life is very limited (approximately 2-3 days) because of the quality loss represented, mainly, by pulp browning and the accumulation of liquid in the packaging.

Controlled atmosphere (CA) and low temperatures provide the maintenance of quality and shelflife prolongation of fruit and vegetables. As every tropical fruit, the pineapple experiences chilling damage when stored at temperatures below 12 °C, OCONNOR-SHAW et al.¹⁴did not observe symptoms of this disturbance in fresh-cut pineapple stored at 4 °C. Oxygen levels below 1% and/or CO₂ levels above 10% are needed to significantly suppress fungal growth^{10, 20}. According to FARBER⁶, the metabolic alterations caused by CO₂ cause the cell stress, resulting in the reduction of microbial growth rates.

The storage of pineapples in CA of 3-5% O₂ + 5-8% CO₂ provides the reduction of respiration rates and the prolongation of its shelf-life. The exposition of this fruit to O₂ levels below 2% and CO₂ levels above 10% seems to favor the development of off-flavors¹². Relatively ampler limits of CO₂ and O₂ (1-20% CO₂ and 2-5% O₂) were established to preserve pineapples¹⁵. However, there is little available information concerningt the ideal conditions of CA to store fresh-cut fruit. It was reported that levels of 10% CO₂ cause the reduction in the deterioration of fresh-cut Champaka pineapples, while O₂ levels below 5% lead to the development of off-flavors from the fermentative metabolism⁹.

The low levels of O₂ used when being stored at 5 °C of fresh-cut Champaka pineapples caused retention of the yellow color, whereas high CO₂ reduced brown discoloration¹³. According to these authors, storing fresh-cut pineapple in 2% O₂ + 10% CO₂ extended post-cutting life for more than two weeks.

Using CA (air + 15% CO₂) reduced color changes in fresh-cut Cantaloupe and Honeydew melons¹⁶. In a similar way, lower alteration in pulp color of fresh-cut Jonagored apples when they were stored in CA of 2% O₂ + 12% CO₂¹⁸was observed.

The purpose of this research was to determine the best gas mixture, in CA conditions, to store fresh-cut Pérola pineapple, particularly in relation to maintaining the visual quality and reduction of microbial growth.

2 Materials and methods

Pineapple fruits (Ananas comosus (L.) Merril, cv. Pérola) were harvested from a commercial grower in Miranorte - TO (Center-West region of Brazil), pre-selected and transported to the "Instituto de Tecnologia de Alimentos" (ITAL), Campinas - SP. Then, the fruit was selected in relation to the size and the shell color (fruit with the fruitlets center yellow), washed with water and neutral detergent and disinfected in 200 mg.L¹ sodium hypochlorite (NaOCl) solution for 2 minutes. Fruit was placed in washed and disinfected (200 mg.L¹NaOCl solution) plastic boxes and kept at 20 °C conditions for approximately 20 hours. After that, the fruit was manually peeled and transversely sliced (approximately 10 mm thick) and the cores were removed^1.

The slices were dipped in a solution of NaOCl (20 mg.L¹) for 30 seconds, which was kept at 10 °C. The excess liquid was drained for 2 minutes and the slices were placed in previously disinfected, air-tight glass jars (3.6 L) which were connected to a flowboard^3,4, installed in a cold room at 5 ± 1 °C. The flowboard system ensured the continuous flow of humid and cold air for 12 days. Gas mixtures were supplied from cylinders connected to the flowboard. Nine controlled atmospheres of 2:5, 2:10, 2:15, 5:5, 5:10, 5:15, 8:5, 8:10 and 8:15 (O₂:CO₂, %) and air were used.

Gas mixture flow was based on the respiration rate of fresh-cut pineapple. Studies carried out with fresh-cut Pérola pineapple showed that respiration rates of slices and chunks were approximately 3.0 mg CO₂.kg¹.h¹ between the 2^nd and 12^th days of storage at 5 ± 1 °C¹.

All the processing was carried out in refrigerated conditions, with temperatures between 12 and 15 °C. The equipment and utensils were disinfected with 200 mg.L¹ NaOCl solution to prevent crossed contamination. Disposable gloves, masks and headwear were used with the same intention.

Fresh-cut pineapple was evaluated on day 0, after sanitation, and at 2, 5, 8 and 12 days. Three replications were used for each treatment. Each replication consisted of a glass jar with eight slices (approximately 0.550 kg). The pulp color was measured with a Minolta Chromameter (Model CR-300, Minolta) in the CIE L*a*b* mode. The L* and a* parameters, recommended for apples², were used to evaluate fresh-cut pineapple browning.

The presence of total coliforms (35 °C) and fecal coliforms (45 °C) in the fresh-cut pineapple was evaluated on day 0. Mesophilic and psychrotrophic aerobic counts were made at 0, 5 and 12 days. Mold and yeast counts were made at 0, 2, 5, 8 and 12 days. The initial evaluation was made after washing with water and neutral detergent. Analyses were carried out according to the methodology described in the Compendium of Methods for the Microbiological Examination of Foods, "APHA"⁵.

The experiment was arranged in completely randomized design, with three replications, where interaction between gas mixture and the storage period were studied. Data were analyzed by analysis of variance (ANOVA) and the separation of means was by Tukeys multiple range test at p < 0.05. Mesophilic and psychrotrophic aerobic, mold and yeast population were transformed into log (x) and expressed in log CFU.g¹.

3 Results and discussion

The pulp color analysis based on the L* value showed that no statistical difference was found between the fruit stored in CA and the control (Figure 1a). There was a slight reduction in this parameter with the storage period for all treatments, attributed to the gradual loss of the samples lightness. The values varied between 75.78 and 71.80 during the period of cold storage, resulting in a reduction of 5.25% (Figure 1c). Similar results were found by GIL et al.⁸, who did not observe statistical differences in the L* value of the pulp color of Fuji apple slices when stored for 3 days in 0.25% O₂ or in air. However, slices stored in 0% O₂ were significantly lighter in color than those stored in either air or 0.25% O₂. In another way, the different conditions of CA (air, 2% O₂, air + 12% CO₂ and 2% O₂ + 12% CO₂) did not interfere in the rapid browning of peaches after slicing¹⁹.

The low O₂ concentrations (2%) with 10% CO₂ or 15% CO₂ resulted in a* values of the pulp color statistically lower than the control. However, no significant difference was found between both gas mixtures (Figure 1b). There was a gradual increase in the a* value from the 2^nd day of storage in CA (Figure 1d). An increase of 22% in this parameter of color was observed, with values between 3.04, on day 0 and 2.37 on the 12^th day of storage. However, this alteration was not visually noticeable. The contribution of red to the color is characterized when the a* values become positive, and this fact was not observed until the end of the storage period.

Total and fecal coliforms were not detected in fresh-cut samples collected on day 0 (after disinfection), which suggest an absence of the microorganisms in the fruit and indicate that processing was carried out under appropriate sanitary conditions.

A relatively low population of mesophilic aerobic, psychrotrophic and mold and yeast (3.65, 1.78 and 3.95 log CFU.g¹, respectively) was observed in the initial evaluation of the fruit, made after washing with neutral detergent and water.

Statistical interaction between the factors (gas mixture and storage period) for mesophilic aerobic and mold and yeast population was observed, but not for psychrotrophic aerobic microorganisms. Regardless of the storage period, the psychrotrophic aerobic population found in the slices stored in CA conditions varied between 2.79 and 4.18 log CFU.g¹, without differing from the population observed in the samples stored in air (3.74 log CFU.g¹). Although not differing from the control, the highest population (4.18 log CFU.g¹) was observed in the samples stored in CA of 8% O₂ + 5% CO₂. Five treatments differed from this one and three of them presented 15% CO₂ in their gas mixture (Figure 2a). Considering the population observed in the initial evaluation (1.78 log CFU.g¹), an increase of 2.0 log cycles was observed on day 0, when the population reached 3.47 log CFU.g¹. Although maintaining itself in 10³ CFU.g¹, a reduction in this count was observed on the 5^th day, followed by an increase that raised the population to levels observed on day 0 (3.44 log CFU.g¹).

The minimal processing of pineapple did not provide an increase in the mesophilic aerobic population, considering the counts in the initial evaluation and on day 0 (3.65 and 3.63 log CFU.g¹, respectively). There were no significant differences between the control and the population of slices stored in CA until the 5^th day of refrigerated storage. In this evaluation, the highest population (4.71 log CFU.g¹) was observed in the samples stored in CA of 8% O₂ + 5% CO₂. On the 12^th day, the mesophilic aerobic population in the slices stored in the CA conditions of 5% O₂ + 15% CO₂ and 8% O₂ + 15% CO₂ were statistically lower than in the control, without differing between them. The CA of 5% O₂ + 15% CO₂ promoted the lowest mesophilic aerobic count (2.83 log CFU.g¹) and reduction in the population by 2.0 log cycles when compared to the control (4.33 log CFU.g¹). The population of 3.09 log CFU.g¹ was observed in slices stored in CA of 8% O₂ + 15% CO₂. Although these gas mixtures provided low counts on the 12^th day, the mesophilic aerobic population presented little variation, with values oscillating between 10² and 10⁴ CFU.g¹ (Figure 3).

A slight reduction in the mold and yeast population was observed on day 0 (3.53 log CFU.g¹) when compared to the initial population (3.95 log CFU.g¹). Up to the 5^thday of storage, there were no significant differences between the control and the population of fresh-cut fruit stored in CA. This behavior was also observed in the mesophilic aerobic population. Although not differing from the control, the highest populations were observed in the slices stored in CA of 8% O₂ + 5% CO₂ on the 2^nd and 5^th days. Statistically lower populations than the control were observed in the slices stored in the CA conditions of 2:10, 2:5, 8:15 and 5:15 (O₂:CO₂, %) on the 8^th day. At this time of evaluation, the lowest mold and yeast count (3.16 log CFU.g¹) was observed in the fresh-cut pineapple stored in CA of 5% O₂ + 15% CO₂. However, this population did not differ from that found in the slices stored in CA of 2:10, 2:5 and 8:15 (O₂:CO₂, %). On the 12^th day, the CA of 5% O₂ + 15% CO₂ provided lower mold and yeast count (3.46 log CFU.g¹) and a reduction in the population by 2.0 log cycles when compared to the control (5.22 log CFU.g¹). However, the population found in this gas mixture did not differ from that observed in the CA conditions of 8:15, 2:15, 2:5, 8:10 and 5:10 (O₂:CO₂, %). Regardless of the fresh-cut pineapple stored in air and CA of 8% O₂ + 5% CO₂ which presented the highest mold and yeast populations at the end of the storage period (5.22 and 6.02 log CFU.g¹, respectively), it was observed that these populations oscillated between 10³ and 10⁴ CFU.g¹ throughout the first 8 days of refrigerated storage (Figure 4).

QI et al.¹⁷ observed lower mesophilic aerobic and mold and yeast population in fresh-cut Honeydew melon, when the cubes were stored in CA of 2% O₂ + 10% CO₂ and 5 °C. However, the mold and yeast population observed in this gas mixture differed from the control only on the 10^th day, and similar behavior was not observed in the mesophilic aerobic population. According to OCONNOR-SHAW et al.¹⁴, the microbial growth did not appear to contribute to spoilage in diced pineapple for 11 days of storage at 4 °C.

In spite of the gas mixture of 5% O₂ + 15% CO₂ having slightly reduced the microbial growth, fresh-cut Pérola pineapple seems to be not very sensitive to storage in CA considering that the slices had little browning and were free of contamination that would affect the food safety at the end of the storage period. Perhaps, maintaining the microbial population in relatively low levels was a result of refrigerated storage, low initial contamination of the intact product and sanitary conditions, and not an effect of the CA storage.

4 Conclusions

Fresh cut Pérola pineapple is not very sensitive to storage in controlled atmosphere. The controlled atmosphere of 5% O₂ + 15% CO₂ slightly reduces the microbial growth in fresh-cut Pérola pineapple.

Acknowledgements

This research received financial support from the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP). The authors would like to thank White Martins Praxair Inc. for supplying the gas mixtures and Débora Belo Alves for her technical contribution to this research.

Recebido para publicação em 14/7/2006

Aceito para publicação em 18/7/2007 (001792)

Apoio Financeiro: FAPESP; PRODETAB/BANCO MUNDIAL

1. ANTONIOLLI, L. R. Processamento mínimo de abacaxi Pérola 2004. 166 p. Tese (Doutorado em Engenharia Agrícola) Universidade Estadual de Campinas, Campinas, 2004. Disponível em: libdigi.unicamp.br/ document/?code=vtls000318352
2. ARTÉS, F.; CASTAÑER, M.; GIL, M. I. Revisión: el pardeamiento enzimático en frutas y hortalizas mínimamente procesadas. Food Science and Technology International, London, v. 4, n. 6, p. 377-389, 1998.
3. CALBO, A. G. Adaptação de um fluxcentro para estudos de trocas gasosas e um método de aferição de capilares. Pesquisa Agropecuária Brasileira, Brasília, v. 24, n. 6, p. 733-739, 1989.
4. CLAYPOOL, L. L.; KEEFER, R. M. A colorimetric method for CO₂ determination. Proceedings of the American Society for Horticultural Science, Alexandria, v. 40, p. 177-186, 1942.
5. DOWNES, F. P.; ITO, K. Compendium of methods for the microbiological examination of foods Washington: American Public Health Association - APHA, 2001. 676 p.
6. FARBER, J. M. Microbiological aspects of modified-atmosphere packaging technology - a review. Journal of Food Protection, Des Moines, v. 54, n. 1, p. 58-70, 1991.
7. GARRETT, E. H. Fresh-cut Produce: Tracks and Trends. In: LAMIKANRA, O. Fresh-cut fruits and vegetables: science, technology, and market. Boca Raton, Florida: CRC Press LLC, 2002, 467 p.
8. GIL, M. I.; GORNY, J. R.; KADER, A. A. Responses of Fuji apple slices to ascorbic acid treatments and low-oxygen atmospheres. HortScience, Alexandria, v. 33, n. 2, p. 305-309, 1998.
9. GORNY, J. R. Packaging design for fresh-cut produce Alexandria: International Fresh-Cut Produce Association, 2003. 122p.
10. KADER, A. A. Biochemical and physiological basis for effects of controlled and modified atmospheres on fruits and vegetables. Food Technology, Chicago, v. 40, n. 5, p. 99-104, 1986.
11. KADER, A. A. Quality parameters of fresh-cut fruit and vegetable products. In: LAMIKANRA, O. Fresh-cut fruits and vegetables: science, technology, and market. Boca Raton, Florida: CRC Press LLC, 2002, 467 p.
12. KADER, A. A. Pineapple: recommendations for maintaining postharvest quality. Disponível em: <http://rics.ucdavis.edu/ postharvest2/Produce/ProduceFacts/Fruit/pineapple.shtml>. Acesso em: 22 jul. 2003.
13. MARRERO, A.; KADER, A. A. Factors affecting the post-cutting life and quality of minimally processed pineapple. Acta Horticulturae, Wageningen, v. 2, n. 553, p. 705-706, 2001.
14. OCONNOR-SHAW, R. E. et al. Shelf life of minimally processed honeydew, kiwifruit, papaya, pineapple and cantaloupe. Journal of Food Science, Chicago, v. 59, n. 6, p. 1202-1206, 1215 p., 1994.
15. OCONNOR-SHAW, R. E. et al. Changes in sensory quality of sterile cantaloupe dice stored in controlled atmospheres. Journal of Food Science, Chicago, v. 61, n. 4, p. 847-851, 1996.
16. PORTELA, S. I.; CANTWELL, M. I. Quality changes of minimally processed honeydew melons stored in air or controlled atmosphere. Postharvest Biology and Technology, Amsterdam, v. 14, n. 3, p. 351-357, 1998.
17. QI, L.; WU, T.; WATADA, A. E. Quality changes of fresh-cut honeydew melons during controlled atmosphere storage. Journal of Food Quality, Trumbull, v. 22, n. 5, p. 513-521, 1999.
18. ROCHA, A. M. C. N.; MORAIS, A. M. M. B. Effects of controlled atmosphere on quality of minimally processed apple (cv. Jonagored). Journal of Food Processing and Preservation, Trumbull, v. 24, n. 6, p. 435-451, 2000.
19. WRIGHT, K. P.; KADER, A. A. Effect of controlled-atmosphere on the quality and carotenoid content of sliced persimmons and peaches. Postharvest Biology and Technology, Amsterdam, v. 10, n. 1, p. 89-97, 1997.
20. ZAGORY, D. Controlled and modified atmospheres. I - General aspects of film technology and selection. In: ANNUAL WORKSHOP FRESH-CUT PRODUCTS: MAINTAINING QUALITY AND SAFETY, 5, 1999, Davis. Proceedings... Davis: University of California, 1998. Section 7a, p. 1-3.

*

A quem a correspondência deve ser enviada

Publication Dates

Publication in this collection
29 Oct 2007
Date of issue
Sept 2007

History

Accepted
18 July 2007
Received
14 July 2006

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. ANTONIOLLI, L. R. Processamento mínimo de abacaxi Pérola 2004. 166 p. Tese (Doutorado em Engenharia Agrícola) Universidade Estadual de Campinas, Campinas, 2004. Disponível em: libdigi.unicamp.br/ document/?code=vtls000318352

[2] 2. ARTÉS, F.; CASTAÑER, M.; GIL, M. I. Revisión: el pardeamiento enzimático en frutas y hortalizas mínimamente procesadas. Food Science and Technology International, London, v. 4, n. 6, p. 377-389, 1998.

[3] 3. CALBO, A. G. Adaptação de um fluxcentro para estudos de trocas gasosas e um método de aferição de capilares. Pesquisa Agropecuária Brasileira, Brasília, v. 24, n. 6, p. 733-739, 1989.

[4] 4. CLAYPOOL, L. L.; KEEFER, R. M. A colorimetric method for CO₂ determination. Proceedings of the American Society for Horticultural Science, Alexandria, v. 40, p. 177-186, 1942.

[5] 5. DOWNES, F. P.; ITO, K. Compendium of methods for the microbiological examination of foods Washington: American Public Health Association - APHA, 2001. 676 p.

[6] 6. FARBER, J. M. Microbiological aspects of modified-atmosphere packaging technology - a review. Journal of Food Protection, Des Moines, v. 54, n. 1, p. 58-70, 1991.

[7] 7. GARRETT, E. H. Fresh-cut Produce: Tracks and Trends. In: LAMIKANRA, O. Fresh-cut fruits and vegetables: science, technology, and market. Boca Raton, Florida: CRC Press LLC, 2002, 467 p.

[8] 8. GIL, M. I.; GORNY, J. R.; KADER, A. A. Responses of Fuji apple slices to ascorbic acid treatments and low-oxygen atmospheres. HortScience, Alexandria, v. 33, n. 2, p. 305-309, 1998.

[9] 9. GORNY, J. R. Packaging design for fresh-cut produce Alexandria: International Fresh-Cut Produce Association, 2003. 122p.

[10] 10. KADER, A. A. Biochemical and physiological basis for effects of controlled and modified atmospheres on fruits and vegetables. Food Technology, Chicago, v. 40, n. 5, p. 99-104, 1986.

[11] 11. KADER, A. A. Quality parameters of fresh-cut fruit and vegetable products. In: LAMIKANRA, O. Fresh-cut fruits and vegetables: science, technology, and market. Boca Raton, Florida: CRC Press LLC, 2002, 467 p.

[12] 12. KADER, A. A. Pineapple: recommendations for maintaining postharvest quality. Disponível em: <http://rics.ucdavis.edu/ postharvest2/Produce/ProduceFacts/Fruit/pineapple.shtml>. Acesso em: 22 jul. 2003.

[13] 13. MARRERO, A.; KADER, A. A. Factors affecting the post-cutting life and quality of minimally processed pineapple. Acta Horticulturae, Wageningen, v. 2, n. 553, p. 705-706, 2001.

[14] 14. OCONNOR-SHAW, R. E. et al. Shelf life of minimally processed honeydew, kiwifruit, papaya, pineapple and cantaloupe. Journal of Food Science, Chicago, v. 59, n. 6, p. 1202-1206, 1215 p., 1994.

[15] 15. OCONNOR-SHAW, R. E. et al. Changes in sensory quality of sterile cantaloupe dice stored in controlled atmospheres. Journal of Food Science, Chicago, v. 61, n. 4, p. 847-851, 1996.

[16] 16. PORTELA, S. I.; CANTWELL, M. I. Quality changes of minimally processed honeydew melons stored in air or controlled atmosphere. Postharvest Biology and Technology, Amsterdam, v. 14, n. 3, p. 351-357, 1998.

[17] 17. QI, L.; WU, T.; WATADA, A. E. Quality changes of fresh-cut honeydew melons during controlled atmosphere storage. Journal of Food Quality, Trumbull, v. 22, n. 5, p. 513-521, 1999.

[18] 18. ROCHA, A. M. C. N.; MORAIS, A. M. M. B. Effects of controlled atmosphere on quality of minimally processed apple (cv. Jonagored). Journal of Food Processing and Preservation, Trumbull, v. 24, n. 6, p. 435-451, 2000.

[19] 19. WRIGHT, K. P.; KADER, A. A. Effect of controlled-atmosphere on the quality and carotenoid content of sliced persimmons and peaches. Postharvest Biology and Technology, Amsterdam, v. 10, n. 1, p. 89-97, 1997.

[20] 20. ZAGORY, D. Controlled and modified atmospheres. I - General aspects of film technology and selection. In: ANNUAL WORKSHOP FRESH-CUT PRODUCTS: MAINTAINING QUALITY AND SAFETY, 5, 1999, Davis. Proceedings... Davis: University of California, 1998. Section 7a, p. 1-3.

Brasil

Brasil

Quality evaluation of fresh-cut ‘Pérola’ pineapple stored in controlled atmosphere

Avaliação da qualidade do abacaxi ‘Pérola’ minimamente processado, armazenado sob atmosfera controlada

Abstracts

Publication Dates

History