Early Detection of Botrytis cinerea Infection in Cut Roses Using Thermal Imaging

( ) causes gray mold disease (GMD), which results in physiological disorders in plants that decrease the longevity and economic value of horticultural crops. To prevent the spread of GMD during distribution, a rapid, early detection technique is necessary. Thermal imaging has been used for GMD detec...

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Bibliographic Details
Published in:Plants (Basel) 2023-12, Vol.12 (24), p.4087
Main Authors: Ha, Suong Tuyet Thi, Kim, Yong-Tae, In, Byung-Chun
Format: Article
Language:English
Subjects:
Biosynthesis
Botrytis cinerea
Disease
Disease control
Flowers
Flowers & plants
Fungi
gray mold disease
Grey mold
Heat detection
Horticultural crops
Infections
Inoculation
mRNA
Multiple regression analysis
petal temperature
Petals
Plant diseases
Plants (botany)
postharvest
Process controls
Reactive oxygen species
rose
Signs and symptoms
Temperature
Thermal imaging
Thermography
vase life
Water balance
Water transport
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Summary:( ) causes gray mold disease (GMD), which results in physiological disorders in plants that decrease the longevity and economic value of horticultural crops. To prevent the spread of GMD during distribution, a rapid, early detection technique is necessary. Thermal imaging has been used for GMD detection in various plants, including potted roses; however, its application to cut roses, which have a high global demand, has not been established. In this study, we investigated the utility of thermal imaging for the early detection of infection in cut roses by monitoring changes in petal temperature after fungal inoculation. We examined the effects of GMD on the postharvest quality and petal temperature of cut roses treated with different concentrations of fungal conidial suspensions and chemicals. infection decreased the flower opening, disrupted the water balance, and decreased the vase life of cut roses. Additionally, the average temperature of rose petals was higher for infected flowers than for non-inoculated flowers. One day before the appearance of necrotic symptoms (day 1 of the vase period), the petal temperature in infected flowers was significantly higher, by 1.1 °C, than that of non-inoculated flowers. The GMD-induced increase in petal temperature was associated with the mRNA levels of genes related to ethylene, reactive oxygen species, and water transport. Furthermore, the increase in temperature caused by GMD was strongly correlated with symptom severity and fungal biomass. A multiple regression analysis revealed that the disease incidence in the petals was positively related to the petal temperature one day before the appearance of necrotic symptoms. These results show that thermography is an effective technique for evaluating changes in petal temperature and a possible method for early GMD detection in the cut flower industry.
ISSN:2223-7747
2223-7747
DOI:10.3390/plants12244087