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Factors affecting mesocarp discolouration severity in 'Pinkerton' avocados (Persea americana MILL.)Van Rooyen, Zelda. January 2005 (has links)
The susceptibility of the 'Pinkerton' avocado cultivar to mesocarp discolouration, after
storage, has seriously threatened its export from South Africa. This disorder has proven to be
complex, requiring a better understanding of the fruit's physiology. The purposes of this
study were to identify the role of pre- and postharvest factors, or their interactions, in the
development of the problem. This was done by obtaining fruit from several production areas
of varying mesocarp discolouration histories (referred to as "high", "medium" or "Iow risk"
areas) during the 2000 and 2001 seasons. Fruit were stored at 8, 5.5 and 2°C for 30 days, as
well as ambient (20°C). Evaluations of fruit quality were made before and after storage, as
well as after softening. Once removed from storage the weight loss (during storage) was
determined, and fruit firmness and carbon dioxide (C02) production rates monitored daily. It
was found that temperatures below the recommended shipping temperature of 5.5°C, i.e.
2°C, produced the best internal fruit quality. This was supported by the membrane integrity
studies that showed less membrane stability at the warmer storage temperature of 8°C.
Furthermore, remained hard during storage and subsequently had an extended shelf life.
Fruit origin was also found to play a major role in browning potential, with discolouration being
consistently more severe in fruit from "high risk" areas and increasing in severity as the
season progressed. The rate of CO2 production was found to follow a similar trend, with rates
increasing as the season progressed, and also being slightly higher in fruit from "high risk"
areas. The higher CO2 production rates were thought to be related to a decrease in
membrane integrity as the season progressed. While storage temperature was not found to
have a significant effect on the rate of CO2 production after storage, it did affect the time taken
to reach the maximum rate, with fruit stored at 2°C taking longer.
Biochemical analyses to determine the concentration of total phenolics and the activity of the
enzyme polyphenol oxidase (PPO) also showed that the potential for browning was initiated
by preharvest conditions. While no significant differences were found between growers with
regards to total phenol concentrations, the PPO activity was found to be higher in fruit from
poor quality areas, and subsequently browning potential was expected to be higher in these
fruit. It was, however, found that the potential for browning could be reduced by storing fruit
at 2°C, as this decreased the total phenolics concentration. This evidence further emphasized
the idea that storage at 2°C could be highly advantageous.
Fruit mineral analysis showed that certain key elements played a significant role in the
severity of mesocarp discolouration, with excessive fruit nitrogen and decreasing copper and
manganese concentrations appearing to play major roles. The high fruit nitrogen
concentrations were suspected to reflect fruit grown on very vigorous trees, resulting in
shoots competing with fruit for available reserves. It is suggested that 'Pinkerton' of a quality
acceptable to the market, can be produced by manipulating source:sink relationships,
particularly through decreasing the availability of nitrogen, followed by low temperature (24°
C) shipping. Future work should concentrate on manipulation of source:sink relationships,
to take account of both climatic conditions and leaf to fruit ratios.
The evaluation of chlorophyll fluorescence as a tool for predicting mesocarp discolouration
potential in 'Pinkerton' proved to be unsuccessful in this study and future studies may require
modifications to the current technique. It is suspected that differences in chlorophyll content,
for example, between fruit from different origins, will have to be taken into account when
interpreting results.
The success of using 2°C storage to improve the internal quality on 'Pinkerton' fruit prompted
further studies, during 2004, to ensure that the development of external chilling injury would
not decrease the marketability of the cultivar. Low temperature conditioning treatments, prior
to storage, proved to be highly successful in reducing the development of external chilling
injury, thus further improving fruit quality as a whole. Preconditioning treatments consisted of
fruit that were kept at either 10°C, 15°C or 20°C for 1 or 2 days before being placed into
storage for 30 days at 2°C or 5.5°C. All preconditioning treatments were compared to fruit that
were placed directly into storage. The effect of fruit packaging on moisture loss (as
determined by weight loss) and chilling injury was also investigated using unwaxed fruit,
commercially waxed and unwaxed fruit individually sealed in micro-perforated polypropylene
bags with an anti-mist coating on the inside (polybags). Holding 'Pinkerton' fruit, regardless of
packaging treatment, at 10°C for 2 days prior to storage at 2°C or 5.5°C significantly
decreased the severity of external chilling injury. The use of polybags during preconditioning
and storage showed potential in further reducing the development of external chilling injury,
although the higher incidence of fungal infections in these fruit needs to be addressed. The
determination of proline concentrations in fruit exocarp tissue after storage was helpful in
determining the level of stress experienced by fruit that were subjected to different packaging
and preconditioning treatments. In this study waxed fruit subjected to 1 d preconditioning at
10°C, 15°C or 20°C or placed directly into storage at 2°C showed very high proline
concentrations and also displayed more severe external chilling injury, despite unwaxed fruit
losing more weight during these treatments. The role of moisture loss thus needs further
investigation. The thickness and method of wax application was thought to play an important
role in the higher external chilling injury ratings in this study as waxed fruit often developed
chilling injury symptoms around the lenticels and it was suspected that either the lenticels
were damaged by the brushes used to apply the wax or that the lenticels became clogged
thus resulting in reduced gaseous exchange. Nevertheless, the success of low temperature
conditioning in reducing external chilling injury, while maintaining sound internal quality, may
enable storage temperatures to be dropped even further, thus enabling South Africa to export
avocados to countries that require a cold disinfestation period prior to entry to eliminate
quarantine pests (e.g. fruit fly). / Thesis (Ph.D.Agric.)-University of KwaZulu-Natal, Pietermaritzburg, 2005.
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Aspekte van sommige ultrastrukturele en fisiologiese veranderinge van avokadovrugte (Persea americana Mill, kultivar Fuerte) gedurende koelopberging en rypwordingKoster, Susanna Aletta 05 February 2014 (has links)
M.Sc. (Botany) / Refer to full text
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Evaluation of an ethanolic extract of propolis as a potential pre- and post-harvest fungicide for 'fuerte' avocado (Persea americana Mill.) fruits and orchidsGiovanelli, Lorenzo Corrado 14 April 2009 (has links)
Abstract
Propolis has been used by man for millennia for its antimicrobial and pharmaceutical
properties. However, its use as an agricultural antimicrobial agent has only recently been
assessed. This study assessed the use of an ethanolic extract of propolis (EEP) for the
control of avocado fruit fungal pathogens. Qualitative analyses of EEP indicated
flavonoids as the main antimicrobial constituents. Quantitative analyses detected 16.35
mg ml-1 total flavonoids and 3.28 mg ml-1 total phenolics. The Minimum Inhibitory
Concentration (MIC) of EEP was determined as 5 mg ml-1 against Colletotrichum
gloeosporioides, Pestalotiopsis guipinii, a complex of Colletotrichum gloeosporioides
and Pseudocercospora sp. (CgP complex), Verticillium sp., Fusarium sp. and Monilia
sp., isolated from avocado fruits, using the agar dilution method, at a concentration
gradient from 1 to 10 mg ml-1. Electron micrographs of Pestalotiopsis guipinii,
Colletotrichum sp. and Colletotrichum gloeosporioides/Pseudocercospora sp. (CgP
complex) incubated on agar media containing EEP clearly indicated signs of cell wall
damage with large pores within the hyphae. Conidial germination of Colletortichum sp.
and P. guipinii was inhibited by 98.95 % and 40.41 % respectively by EEP. Trees
infected with Colletotrichum sp., P. guipinii or CgP complex conidia were incubated
within greenhouse conditions and treated with 5 mg ml-1 EEP at weekly intervals from
once every week to once every six weeks. Disease indices from experimental and control
trees were similar but noticeable control of CgP disease symptoms was observed from
treatment with EEP. ‘Fuerte’ avocado trees were treated with copper hydroxide, borehole
water or 5 mg ml-1 EEP during the 2006-2007 growing season. All fruit were similar
after harvesting with respect to pre-harvest disease. The occurrence of post-harvest
diseases was analysed after simulations of import and export markets. EEP treated fruit
were similar to bore-hole treated fruits (control). Similar results were observed after trials
to assess the use of EEP as a post-harvest dip. The stem-end of prematurely harvested
‘Fuerte’ fruit were dipped into 5 mg ml-1 EEP, and incubated until ripe, to assess control
of stem-end rot (SER). EEP reduced the occurrence of SER by 30 %. EEP was further
assessed to inhibit infection or disease spread by Colletotrichum conidia. Fruits were
inoculated with Colletotrichum conidia and either treated with 5 mg ml-1 or 10 mg ml-1
EEP either after or before infection. The fruits were incubated until ripe. Both treatments
reduced the occurrence of disease (P < 0.001). In conclusion, EEP did not efficiently control disease in the field, but showed high potential as a future fungicide for avocado
fruit. Optimisation of EEP includes higher concentrations, the addition of stickers, and/or
more frequent spraying of trees.
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Effect of tree girdling, harvest time and ripening temperature on "hass" avocado fruit skin colour development during ripeningSibuyi, Hazel January 2018 (has links)
Thesis (M.Sc. (Horticulture)) --University of Limpopo, 2018 / ‘Hass’ avocado fruit changes skin colour from green to purple and then black during ripening. However, markets importing South African avocado fruit have been complaining about the ‘Hass’ skin colour not changing to purple/black during ripening. Thus, the study aimed to investigate the effect of tree girdling, harvest time and ripening temperature on ‘Hass’ avocado fruit skin colour development during ripening. The mature ‘Hass’ avocado fruit were harvested from girdled and non-girdled trees during early (April), mid- (May) and late (June) harvest times. Upon arrival, in the laboratory fruit were cold stored at 5.5°C for 28 days. After storage, fruit were ripened at 25, 21 and 16°C for 8, 6 and 4 days, respectively. After withdrawal from clod storage fruit were evaluated for skin colour development, ripening and physiological disorders (chilling injury). Fruit from girdled trees showed high maturity (low moisture content) when compared with fruit from non-girdled trees during early and mid-harvest. With respect to skin colour development, the results indicate that skin eye colour development of fruit from girdled and non-girdled trees minimally increased from emerald green (1) to olive green (3) across all harvest times, ripening temperature and ripening duration. However, late season fruit from non-girdled trees improved to purple (4) when ripened at 21°C when compared with fruit from girdled trees. In terms of objective colour, lightness, hue angle and chroma decreased for fruit from girdled and non-girdled trees, across all harvest times, ripening temperature and ripening duration. Lightness and hue angle of fruit from girdled trees were slightly reduced when compared with fruit from non-girdled trees, throughout all harvest times, ripening temperature and duration. Early and mid-season fruit harvested from girdled trees showed rapid decrease of chroma when compared with fruit from non-girdled trees, throughout ripening temperature and
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duration. In terms of softening, fruit from girdled trees showed higher firmness loss and ripening percentage within 6 (16°C) and 4 (21 and 25°C) days when compared with fruit from non-girdled trees during early and mid-harvest, whereas, late harvest fruit from girdled trees reached higher ripening percentage and firmness loss within 4 days throughout ripening temperatures. With respect to cold damage, late harvested fruit from girdled trees showed higher external chilling injury when compared with non-girdled trees, throughout ripening temperature. In general, girdling treatment improved fruit maturity, ripening rate and firmness loss. However, the incidence of variable skin colouring of ‘Hass’ avocado fruit during ripening was also prevalent in early harvested fruit from girdled tree, irrespective of ripening temperature.
Keywords: girdling, harvest time, physiological disorder, ripening temperature, variable colouring
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Avocado fruit responses to Colletotrichum gloeosporioides /Giblin, Fiona Rosanna. January 2005 (has links) (PDF)
Thesis (Ph.D) - University of Queensland, 2006. / Includes bibliography.
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Invloed van kalsiumtoedienings op aspekte van die ultrastruktuur en sekere ensieme van avokadovrugteSteyn, Gerhard 23 July 2014 (has links)
M.Sc. (Botany) / Please refer to full text to view abstract
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Evaluation of hot water and hot air heat shock treatments on South African avocados to minimise the occurrence of chilling injuryKritzinger, Madeleine 12 1900 (has links)
Thesis (MSc Food Sc)--Stellenbosch University, 2002. / ENGLISH ABSTRACT: The South African avocado fruit industry is export driven and the successful
storage of fruits for extended periods is, therefore, essential. It was recorded
that 7.7 million cartons were exported during the 1995 season. The shipping
of the avocados takes approximately 15 days and the fruits are being stored
at low temperatures to minimise the possibility of fruits softening.
Unfortunately low temperature storage results in chilling injury. A possible
method to increase avocado resistance to chilling injury is to administer a heat
shock treatment. In this way the fruits are protected from chilling injury by
inducing the formation of so-called heat-shock proteins which render the cell
membranes more resistant to chilling injury.
The objective of this study was to evaluate different heat shock
treatment protocols as a method of preventing or minimising chilling injury and
to extend the shelf-life of avocado fruits while exporting at the lowest possible
temperature. Examining the effect of different temperatures and exposure
times on the quality of the different avocado cultivars pursued this. The
exterior chilling injury on each fruit was quantified and the firmness and
internal quality parameters evaluated.
A total of 32 Experimental Studies were conducted. The results
showed that the Hot Water Heat shock Treatment (HWHST) worked
effectively for the South African 'Fuerte' cultivar between 40° and 42°C for
exposure times of between 20 and 30 min. The 'Edranol' cultivar also showed
promising results between 40° and 42°C for exposure time of between 8 and
22 min. The HWHST was not effective on the South African 'Hass' cultivar.
The 'Ryan' cultivar with its thick skin made this cultivar less susceptible to
chilling injury and therefore HWHST would be unnecessary. The 'Pinkerton'
cultivar had a lot of factors that influenced the results. Therefore, more
research needed to be done on the 'Pinkerton' cultivar, before any
conclusions could be obtained from this cultivar, although it showed potential.
Hot air treatment worked fairly well, but unfortunately the long exposure time
needed made this treatment unpractical. Throughout the whole study the
importance of maturity surfaced as a major role in all the aspects of post
harvest quality. / AFRIKAANSE OPSOMMING: Die Suid-Afrikaanse avokado vrugtebedryf is hoofsaaklik gerig op die
uitvoermark en daarom is dit belangrik dat die vrugte vir 'n bepaalde tyd
suksesvolopgeberg kan word. Die sensus opname gedurende die 1995
seisoen het getoon dat 7.7 miljoen bokse avokados uitgevoer is. Die
avokados word vir ongeveer 15 dae per boot vervoer, wat kan lei tot vrugte
wat sag word. Om dit te verhoed, word die vrugte by lae temperature
opgeberg. Ongelukkig veroorsaak lae opbergingstemperature koueskade. 'n
Moontlike metode om avokados te beskerm teen lae temperature en
koueskade te verminder, is om 'n hitteskok behandeling toe te pas. Op
hierdie manier word die vrugte beskerm teen koueskade deur die vorming van
sogenaamde hitteskok proteïene wat die selwande meer bestand maak teen
koueskade.
Die doel van hierdie studie was om die verskillende hitteskok
behandelings protokols te evalueer as 'n metode van beskerming of
vermindering van koueskade en om sodoende die rakleeftyd van avocados te
verleng as die vrugte by lae temperature uitgevoer word. Eksperimente is
uitgevoer om die effek van verskillende temperature en blootstellingstye op
die kwaliteit van die verskillende avokado kultivars te bepaal. Die koueskade
op die oppervlakte van elke vrug is bepaal en die fermheid en interne kwaliteit
parameters is geëvalueer.
In totaal is daar altesaam 32 Eksperimentele Studies gedoen. Die
resultate het gewys dat die Warm Water Hitteskok Behandeling (WWHB)
effektief was op die Suid-Afrikaanse 'Fuerte' kultivar by temperature tussen
40° en 42°C en by blootstellingstye van tussen 20 en 30 min. Belowende
resultate is ook met die 'Edranol' kultivar by temperature tussen 40° en 42°C
met blootstellingtye van tussen 8 en 22 min behaal. Die WWHB was
oneffektief vir die Suid-Afrikaanse 'Hass' kultivar. Die 'Ryan' kultivar se dik
skil het hierdie kultivar minder vatbaar gemaak vir koueskade en daarom was
'n WWHB onnodig gewees. By die 'Pinkerton' kultivar kon daar nog nie 'n
gevolgtrekking gemaak word nie, aangesien daar nog baie faktore is wat
ondersoek moet word, alhoewel die kultivar baie potentiaal getoon het. Warm
lug behandeling het potensiaal gehad, maar die lang blootstellingstye het hierdie behandeling onprakties gemaak. Gedurende die hele studie is daar
klem gelê op die rypheisgraad van die vrugte wat na vore gekom het as 'n
belangrike faktor wat 'n hoofrol speel in al die aspekte van die na-oes
kwaliteit.
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Comparative studies of Dothiorella on avocadoSchoeman, Margareth Vuyiswa 10 October 2005 (has links)
A market survey was conducted to determine the incidence of stem-end rot (SE) on avocado fruit obtained from the Pretoria Fresh Produce Market representing the Tzaneen production area. Dothiorella aromatica isolates collected from this survey were compared in terms of physiological characteristics i.e. growth and temperature, carbon and nitrogen utilization and pH response as well as genetic relatedness using random amplified polymorphic DNA (RAPD's). The incidence of SE was found to be as high as 31% and anthracnose 18%. Symptom development was more apparent when fruit was evaluated at the overripe than eating ripe stage. Of the 12 identified fungi isolated from SE lesions, D. aromatica was by far the most frequently isolated fungus. All D. aromatica isolates tested were found to be pathogenic using the fruit inoculation technique. Based on lesion size, isolates were separated into two groups of virulent and less virulent. Most isolates grouped within the one cluster, with only one isolate falling in the second group being less virulent. Although similar groupings were found between physiological tests, a lack of consistency as to which isolate belonged to which group was found. The optimum temperature for growth was 25°C and an initial pH of 6. The mean colony growth rate was 5 mm day-1. Isolates grew at a minimum of eight to a maximum of 27 mm within 24 hours. Isolates grew best on pectin and poorly on sorbitol when used as a carbon source. Urea supported growth best and poor growth was found on casein-amended sources. At a molecular level, the RAPD technique could be used successfully to seperate isolates into three groups based on cluster analyses. OPC02 was the most discrimatory primer and was therefore used in this study. Isolates produced DNA fragments ranging from 1500 bp to 450 bp. The results obtained from RAPDs could not be correlated with the pathogenicity and physiological tests. Future studies should focus on comparing isolates from different avocado production areas and testing different primers for the ability to distinguish between isolates of D. aromatica. / Dissertation (MInst Agrar (Plant Protection))--University of Pretoria, 2005. / Microbiology and Plant Pathology / unrestricted
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An elucidation of selected pre-harvest practices and postharvest treatment influencing 'Hass' avocado fruit exocarp colour development during ripeningShikwambana, Kingsly January 2022 (has links)
Thesis (Ph.D. (Plant Production)) -- University of Limpopo, 2022 / In 'Hass' avocado fruit, pre-harvest and postharvest factors affecting exocarp colour
change during ripening are vital to maintain the industry’s credibility, competitiveness
and profitability. Currently, the South African ‘Hass’ avocado fruit exocarp colour
development is affected by pre- and postharvest factors, ultimately, fruit does not
develop the required purple colour during ripening. These pre- and postharvest factors
must be understood in order to implement strategies that avoid downgrading of South
African 'Hass' avocado fruit by lucrative markets due to insufficient purple colour
development during ripening. In 'Hass' avocado fruit, exocarp colour development is
associated with an increase in anthocyanin synthesis and accumulation during
ripening. However, limited information is available regarding factors regulating
anthocyanin synthesis and accumulation in 'Hass' avocado fruit during ripening.
Therefore, the overall aims of this study were to investigate pre-harvest practices and
postharvest treatment that increase exocarp anthocyanin synthesis during ripening. In
addition, determine whether exocarp glucose and other antioxidants contribute to
'Hass' avocado fruit exocarp colour development during ripening.
In chapter 3, the study looked at how crop load adjustment affects ‘Hass’ avocado fruit
exocarp colour development during ripening at three different harvest maturities. The
crop load adjustment treatments were applied as: high (100%), moderate (50%) and
low (25%) at three harvest times (early, mid- and late). After harvest, fruit were stored
at 5.5°C for 28 days, thereafter, ripened at 25°C. The experimental design was carried
out as 3 x 3 factorial, arranged in a completely randomized design (CRD) with three
replications. The results showed that total anthocyanin and cyanidin 3-O-glucoside concentrations of ‘Hass’ avocados increased following crop load adjustment from
normal (100%) to moderate (50%) and low (25%) loads, resulting in improved exocarp
colour development during ripening. Furthermore, we discovered that fruit harvested
from moderate (50%) and low (25%) crop loads accumulated higher exocarp sugars
(D-mannoheptulose and perseitol) at three harvest maturities when compared with
high crop load (100%). Moreover, total phenolic concentration of fruit harvested from
moderate (50%) and low (25%) crop loads was higher than that obtained from high
load fruits, irrespective of harvest maturities.
In chapter 4, the study examined the interaction between branch girdling and harvest
maturation on the development of 'Hass' avocado fruit exocarp colour during ripening.
The experimental design was carried out as 2 x 2 factorial, arranged in a completely
randomized design (CRD). The results showed that fruit harvested from girdled trees
had poor exocarp colour development as compared to fruit harvested from control
trees, regardless of harvest time. Fruit harvested from girdled and ungirdled avocado
trees did not show significant differences in visual exocarp colour during early and
mid-maturity. Apart from crop load adjustment and girdling as pre-harvest methods to
manipulate postharvest exocarp colour, glucose was also infused through the pedicel.
Studies on the effect of glucose infusion through the pedicel on the exocarp colour of
the ‘Hass’ avocado fruit during ripening were presented in chapter 5. The study
included five treatments; control fruit with pedicel and infused with distilled water and
glucose concentrations (0.05, 0.13 and 0.28 mM). The distilled water, glucose infused
and control fruit were stored at 5.5°C for up to 28 days. After cold storage, fruit were
kept at ambient temperature 25°C for ripening. The experiment was conducted as a
completely randomized design (CRD) with three replications per treatment. The results
showed that glucose infusion through the pedicel markedly increased anthocyanin and
cyanidin 3-O-glucoside concentration during ripening. Interestingly, glucose
concentrations (0.05 and 0.13 mM) resulted in purple colour development after 8 days
at 25°C when compared with control, distilled water and highest concentration (0.28
mM).
In chapter 6, the relationship between 'Hass' avocado fruit size, exocarp colour and
related pigments with antioxidants capacity and sugar concentration during ripening
were investigated. The fruit were categorized by their weight; small (< 200 g) and large
(> 201 g). Their diameter and length were also measured using a vernier calliper. Fruit
ware stored at 5.5°C for 28 days, then ripened at 25°C. The experimental design was
carried out as a completely randomised design (CRD), using 25 fruit replications per
category. The results showed that small-sized fruit developed the desirable purple to
black exocarp colour when compared with large-sized fruit. Additionally, the results
showed that small-sized fruit had higher antioxidant capacity as measured by 2,2
diphenyl 1 picrylhydrazyl (DPPH), ascorbic acid and flavonoid content during ripening
when compared with large-sized fruit. Furthermore, it was found that small-sized fruit
accumulated higher exocarp and seeds (D-mannoheptulose, perseitol, sucrose and
glucose) sugar concentration. We demonstrated and concluded that exocarp colour,
pigments, antioxidants and sugar concentration are closely related to size in 'Hass'
avocado fruit. Knowledge from this thesis contributes toward the understanding of pre and postharvest factors that may influence colour development of ‘Hass’ avocado fruit
during ripening. This study contributes towards bridging the gap in the literature on the
biochemical changes associated with colour development of ‘Hass’ avocado fruit
during ripening / Agricultural Research Council-Tropical
and Subtropical Crops (ARC-TSC) and National Research Foundation (NRF)
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Effect of harvest time, post-harvest storage and ripening temperature on fruit quality of reed avocado cultivarShikwambana, Kingsly January 2016 (has links)
Thesis (M. Sc. (Agriculture, Horticulture)) --University of Limpopo, 2016 / ‘Reed’ avocado is a late season cultivar introduced to South Africa from California. The cultivar has shown good adaptation and produces quality fruit with export potential. Its pre-harvest adaptation and production aspects have been researched and documented. However, the effect of harvest time, post-harvest storage and ripening temperature has not been comprehensively studied on this newly introduced ‘Reed’ avocado cultivar. Therefore, the aim of this work was to investigate the effect of different harvest time, post-harvest storage and ripening temperature on the quality of late season ‘Reed’ avocado fruit. Matured ‘Reed’ avocado fruit were harvested based on moisture content indexing in December (2015) and January (2016). The experiment was carried out in a factorial, arranged in a completely randomised design (CRD) with three replicates. Treatment factors were: 2 x harvest time (mid-and late), 2 x post-harvest storage (2.0 and 5.5°C), 3 x ripening temperature (16, 21 and 25°C) and 5 x ripening day (0, 2, 4, 6 and 8). Fruit were stored at 2.0 and 5.5°C for 28 days, thereafter, ripened at 16, 21 and 25°C until fully ripe. During ripening, fruit were evaluated for weight loss, skin colour, firmness, respiration rate, physiological and pathological disorders. Mid-harvest fruit had higher moisture content when compared with late harvest fruit. However, harvest time, post-harvest storage, ripening temperature and ripening time (days) significantly influenced fruit weight loss, firmness, respiration rate, ripening percentage of ‘Reed’ avocado fruit during ripening. Moreover, fruit firmness decreased faster at higher temperatures (25 and 21°C) with fruit ripening within 4 and 6 days, respectively. In addition, ripening at a lower temperature (16°C) was slower with fruit fully ripened within 8 days after withdrawal from cold storage at both harvest times. ‘Reed’ avocado fruit respiration rate followed a climacteric pattern, however, significantly higher rate at higher temperature (25°C) when compared with lower temperature (16°C) after withdrawal from cold storage during both harvest times. Interestingly, mid-harvest fruit showed high electrolyte damage after withdrawal from 2.0°C when compared with late harvest fruit at the same temperature. Furthermore, mid-harvest fruit stored at 2.0ºC and ripened at 21°C showed higher chilling injury when compared with fruit ripened at 16 and 25°C. High electrolyte leakage positively correlated (R2 = 0.242) with high chilling damage for
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mid-harvest fruit stored 5.5°C. Treatment factors had a significant effect (P < 0.05) on lightness (L *) and hue angle (h
) but no significant effect (P > 0.05) on chroma (C *) and eye colour of ‘Reed’ avocado fruit during ripening, irrespective of harvest time. Overall results showed a visual change in ‘Reed’ avocado skin colour, with eye colour changing from green to bright yellow. Furthermore, late harvest fruit showed high post-harvest pathological diseases after removal from high temperature (5.5°C) when compared with mid-harvest fruit stored at low storage temperature (2.0°C). Ripening at a higher temperature (21 and 25°C) resulted in higher incidence of stem-end rot and body rot when compared with lower temperature (16°C) for both harvest times. Late harvest fruit showed a higher incidence of vascular browning at higher ripening temperatures (21 and 25°C) when compared with lower temperature (16°C) after withdrawal from cold storage. Moreover, overall results showed that harvest time, post-harvest storage and the ripening temperature had a profound influence on the quality of ‘Reed’ avocado fruit. In conclusion, ‘Reed’ avocado fruit can be harvested during mid- or late season and stored at recommended low temperature (2.0ºC); and thereafter, ripened at either 16 or 21ºC. In addition, future studies should focus on identifying pre-harvest practices that promote higher post-harvest fruit quality for ‘Reed’ avocado fruit under South African production environment.
Keywords: ‘Reed’ avocado fruit; firmness; electrolyte leakage; respiration rate; stem-end rot; body rot; vascular browning
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