Hyperspectral response of cape gooseberry (Physalis peruviana L.) plants inoculated with Fusarium oxysporum f. sp. physali for vascular wilt detection

Giraldo-Betancourt, Cristhian; Velandia-Sánchez, Edisson Andrés; Fischer, Gerhard; Gómez-Caro, Sandra; Martínez, Luis Eduardo Cruz

doi:10.17584/rcch.2020v14i3.10938

Cited by 7 publications

(5 citation statements)

References 52 publications

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“…The decrease in the absorbance of red light, therefore, is a sign of a non-effective quantum yield of PSII and PSI [89], which in the initial stage of the wilting progression can be explained by the degradation of chlorophyll a and peroxidation of the thylacoid plasmalemma due to the photoprotective action of ethylene induced by exposure to F. oxysporum toxin, accompanied also by a significant reduction in stomatal conductance [90]. Indeed, this evidence is consistent with the results of previous research concerning chlorophyll-associated VIs that are highly correlated with F. oxysporum disease progression on Physalis peruviana L. [91], and on banana [92]. These results highlighted the importance of capturing hyperspectral information on chlorophyll a transported by PSII in the phospholipidic membrane of thylacoids, to detect early infections of F. oxysporum f. sp.…”

Section: Discussionsupporting

confidence: 91%

Early Detection of Wild Rocket Tracheofusariosis Using Hyperspectral Image-Based Machine Learning

et al. 2021

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Fusarium oxysporum f. sp. raphani is responsible for wilting wild rocket (Diplotaxis tenuifolia L. [D.C.]). A machine learning model based on hyperspectral data was constructed to monitor disease progression. Thus, pathogenesis after artificial inoculation was monitored over a 15-day period by symptom assessment, qPCR pathogen quantification, and hyperspectral imaging. The host colonization by a pathogen evolved accordingly with symptoms as confirmed by qPCR. Spectral data showed differences as early as 5-day post infection and 12 hypespectral vegetation indices were selected to follow disease development. The hyperspectral dataset was used to feed the XGBoost machine learning algorithm with the aim of developing a model that discriminates between healthy and infected plants during the time. The multiple cross-prediction strategy of the pixel-level models was able to detect hyperspectral disease profiles with an average accuracy of 0.8. For healthy pixel detection, the mean Precision value was 0.78, the Recall was 0.88, and the F1 Score was 0.82. For infected pixel detection, the average evaluation metrics were Precision: 0.73, Recall: 0.57, and F1 Score: 0.63. Machine learning paves the way for automatic early detection of infected plants, even a few days after infection.

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Section: Discussionsupporting

confidence: 91%

Early Detection of Wild Rocket Tracheofusariosis Using Hyperspectral Image-Based Machine Learning

et al. 2021

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“…Crops infected with this phytopathogen experience fusariosis, a plant disease that causes damage from leaf chlorosis to vascular necrosis [ 24 ]. These adverse effects produce significant economic losses in the agricultural sector [ 25 ], specifically in crops such as cape gooseberrys [ 26 ], bananas [ 27 ], carnations [ 28 ], lulos, and strawberries [ 29 ]. Fungicides such as dithane-M45, manzate 200WP, fitoraz, rovral-Flo, folicur EW, stroby SC, azoxystrobin, benomyl, carbendazim, and fludioxonil are currently used for the management of fusariosis [ 30 , 31 ].…”

Section: Introductionmentioning

confidence: 99%

Quinolizidine-Based Variations and Antifungal Activity of Eight Lupinus Species Grown under Greenhouse Conditions

2022

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Fusarium oxysporum is an aggressive phytopathogen that affects various plant species, resulting in extensive local and global economic losses. Therefore, the search for competent alternatives is a constant pursuit. Quinolizidine alkaloids (QA) are naturally occurring compounds with diverse biological activities. The structural diversity of quinolizidines is mainly contributed by species of the family Fabaceae, particularly the genus Lupinus. This quinolizidine-based chemo diversity can be explored to find antifungals and even mixtures to address concomitant effects on F. oxysporum. Thus, the antifungal activity of quinolizidine-rich extracts (QREs) from the leaves of eight greenhouse-propagated Lupinus species was evaluated to outline promising QA mixtures against F. oxysporum. Thirteen main compounds were identified and quantified using an external standard. Quantitative analysis revealed different contents per quinolizidine depending on the Lupinus plant, ranging from 0.003 to 32.8 mg/g fresh leaves. Bioautography showed that all extracts were active at the maximum concentration (5 µg/µL). They also exhibited >50% mycelium growth inhibition. All QREs were fungistatic except for the fungicidal QRE of L. polyphyllus Lindl. Angustifoline, matrine, 13α-hydroxylupanine, and 17-oxolupanine were ranked to act jointly against the phytopathogen. Our findings constitute reference information to better understand the antifungal activity of naturally afforded QA mixtures from these globally important plants.

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“…2 chlorophyll content indicators, one of the more common indices is the Normalized Difference Vegetation Index (NDVI), which correlates with the amount of biomass, chlorophyll content and nitrogen content (Ranjan and Parida, 2020). There are other indexes for monitoring the nutritional status of crops, such as the Optimized Soil-adjusted Vegetation Index (OSA-VI) and the Near-infrared/red Ratio (NIR/red), which minimize the effect of soil reflectance on vegetation responses, as compared to NDVI, the Modified Chlorophyll Absorption Ratio (MCARI) and the Near-Infrared/green Ratio (NIR/green), which are more responsive to the leaf chlorophyll content (Daughtry et al, 2000;Giraldo-Betancourt et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Estimating chlorophyll and nitrogen contents in maize leaves (Zea mays L.) with spectroscopic analysis

Ramos-García

Martinez

2022

Rev. Colomb. Cienc. Hortic

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The relationship between reflectance and chlorophyll (Chl) and nitrogen (N) contents in maize leaves was analyzed to identify useful spectral indices for diagnosing the nutritional status of crops in terms of N. An experiment was carried out in random blocks with five treatments of nitrogen fertilizer (0, 50, 100, 150, 200 kg ha-1) and four repetitions and the foliar spectral responses were measured with a FieldSpec 4 spectroradiometer in three phenological stages. Several spectral indices and values of red edge position (REP) were calculated using various methods. Red-edge position linear interpolation (REP-L), Red-edge position linear extrapolation (REP-LE), REP-Inverted Gaussian fitting technique (REP-IG), REP-Polynomial fitting technique (REP-P) and NDVI had the best relationship with chlorophyll and nitrogen contents. The first derivative of reflectance, between 560 and 760 nm, transformed by the normal state variable (SNV) also had highly significant correlation coefficients with the N, Chl, and yield. Additionally, the corn yield showed highly significant correlations with the N and Chl contents. From the point of view of the diagnosis of the nutritional status of corn, the spectral indices and REP values were suitable for establishing the nutritional status of corn in relation to N in the phenological stages V8 and R1.

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Hyperspectral response of cape gooseberry (Physalis peruviana L.) plants inoculated with Fusarium oxysporum f. sp. physali for vascular wilt detection

Cited by 7 publications

References 52 publications

Early Detection of Wild Rocket Tracheofusariosis Using Hyperspectral Image-Based Machine Learning

Early Detection of Wild Rocket Tracheofusariosis Using Hyperspectral Image-Based Machine Learning

Quinolizidine-Based Variations and Antifungal Activity of Eight Lupinus Species Grown under Greenhouse Conditions

Estimating chlorophyll and nitrogen contents in maize leaves (Zea mays L.) with spectroscopic analysis

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