Postharvest osmotic dehydration of pedicels of sweet cherry fruit

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Moritz Knoche
  • Thomas O. Athoo
  • Andreas Winkler
  • Martin Brüggenwirth

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Details

Original languageEnglish
Pages (from-to)86-90
Number of pages5
JournalPostharvest biology and technology
Volume108
Early online date25 Jun 2015
Publication statusPublished - 1 Oct 2015

Abstract

The appearance of the pedicels is a good indicator of postharvest freshness of sweet cherry fruit (Prunus avium L.). Shrivelled pedicels are thought to result from water loss due to pedicel transpiration after extended periods of storage or after storage under inferior (drying) conditions. This study establishes that osmotic dehydration can also be a factor in pedicel deterioration during storage. A time course study revealed that the water content of a pedicel attached to its fruit and incubated at 100% relative humidity (RH) decreased within 24. h and remained approximately constant thereafter. In contrast, the water content of a detached pedicel, increased slightly and continuously over nine days. Similarly, pedicel diameter decreased when a pedicel remained attached to its fruit but did not decrease when it was detached. Pedicels that remained attached to their fruit yellowed more rapidly than the ones that had been detached. Pedicel dehydration was not related to pedicel transpiration, as this was effectively zero at 100% RH. The decrease in water content of attached pedicels was accompanied by a corresponding increase in osmolarity. However, the osmolarity of detached pedicels decreased slightly. Potometry revealed a continuous flow of water through the pedicel into the fruit even though the fruit was held under non-transpiring conditions (100% RH). When a fruit and pedicel was mounted on a pressure probe (100% RH), a slight negative pressure developed that gradually approached an equilibrium value of -30.3. ±. 2.0. kPa. Our results demonstrate that osmotic dehydration accounts for pedicel shrivelling recorded at 100% RH.

Keywords

    Osmotic potential, Stalk, Xylem

ASJC Scopus subject areas

Cite this

Postharvest osmotic dehydration of pedicels of sweet cherry fruit. / Knoche, Moritz; Athoo, Thomas O.; Winkler, Andreas et al.
In: Postharvest biology and technology, Vol. 108, 01.10.2015, p. 86-90.

Research output: Contribution to journalArticleResearchpeer review

Knoche M, Athoo TO, Winkler A, Brüggenwirth M. Postharvest osmotic dehydration of pedicels of sweet cherry fruit. Postharvest biology and technology. 2015 Oct 1;108:86-90. Epub 2015 Jun 25. doi: 10.1016/j.postharvbio.2015.05.014
Knoche, Moritz ; Athoo, Thomas O. ; Winkler, Andreas et al. / Postharvest osmotic dehydration of pedicels of sweet cherry fruit. In: Postharvest biology and technology. 2015 ; Vol. 108. pp. 86-90.
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title = "Postharvest osmotic dehydration of pedicels of sweet cherry fruit",
abstract = "The appearance of the pedicels is a good indicator of postharvest freshness of sweet cherry fruit (Prunus avium L.). Shrivelled pedicels are thought to result from water loss due to pedicel transpiration after extended periods of storage or after storage under inferior (drying) conditions. This study establishes that osmotic dehydration can also be a factor in pedicel deterioration during storage. A time course study revealed that the water content of a pedicel attached to its fruit and incubated at 100% relative humidity (RH) decreased within 24. h and remained approximately constant thereafter. In contrast, the water content of a detached pedicel, increased slightly and continuously over nine days. Similarly, pedicel diameter decreased when a pedicel remained attached to its fruit but did not decrease when it was detached. Pedicels that remained attached to their fruit yellowed more rapidly than the ones that had been detached. Pedicel dehydration was not related to pedicel transpiration, as this was effectively zero at 100% RH. The decrease in water content of attached pedicels was accompanied by a corresponding increase in osmolarity. However, the osmolarity of detached pedicels decreased slightly. Potometry revealed a continuous flow of water through the pedicel into the fruit even though the fruit was held under non-transpiring conditions (100% RH). When a fruit and pedicel was mounted on a pressure probe (100% RH), a slight negative pressure developed that gradually approached an equilibrium value of -30.3. ±. 2.0. kPa. Our results demonstrate that osmotic dehydration accounts for pedicel shrivelling recorded at 100% RH.",
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AU - Athoo, Thomas O.

AU - Winkler, Andreas

AU - Brüggenwirth, Martin

N1 - Funding Information: We thank Friederike Schroeder and Simon Sitzenstock for technical assistance, Drs. Sandy Lang and Bishnu P. Khanal for helpful comments on an earlier version of this manuscript. This research was funded in part by a grant from the Deutsche Forschungsgemeinschaft and the Marktgemeinschaft Altes Land.

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N2 - The appearance of the pedicels is a good indicator of postharvest freshness of sweet cherry fruit (Prunus avium L.). Shrivelled pedicels are thought to result from water loss due to pedicel transpiration after extended periods of storage or after storage under inferior (drying) conditions. This study establishes that osmotic dehydration can also be a factor in pedicel deterioration during storage. A time course study revealed that the water content of a pedicel attached to its fruit and incubated at 100% relative humidity (RH) decreased within 24. h and remained approximately constant thereafter. In contrast, the water content of a detached pedicel, increased slightly and continuously over nine days. Similarly, pedicel diameter decreased when a pedicel remained attached to its fruit but did not decrease when it was detached. Pedicels that remained attached to their fruit yellowed more rapidly than the ones that had been detached. Pedicel dehydration was not related to pedicel transpiration, as this was effectively zero at 100% RH. The decrease in water content of attached pedicels was accompanied by a corresponding increase in osmolarity. However, the osmolarity of detached pedicels decreased slightly. Potometry revealed a continuous flow of water through the pedicel into the fruit even though the fruit was held under non-transpiring conditions (100% RH). When a fruit and pedicel was mounted on a pressure probe (100% RH), a slight negative pressure developed that gradually approached an equilibrium value of -30.3. ±. 2.0. kPa. Our results demonstrate that osmotic dehydration accounts for pedicel shrivelling recorded at 100% RH.

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