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1.
Plant Disease Models and Forecasting: Changes in Principles and Applications over the Last 50 Years.
Phytopathology
; 113(4): 678-693, 2023 Apr.
Artículo
en Inglés
| MEDLINE | ID: mdl-36624723
2.
Nitrogen use efficiency, rhizosphere bacterial community, and root metabolome reprogramming due to maize seed treatment with microbial biostimulants.
Physiol Plant
; 174(2): e13679, 2022 Mar.
Artículo
en Inglés
| MEDLINE | ID: mdl-35362106
3.
Development and Evaluation of a Model that Predicts Grapevine Anthracnose Caused by Elsinoë ampelina.
Phytopathology
; 111(7): 1173-1183, 2021 Jul.
Artículo
en Inglés
| MEDLINE | ID: mdl-33295782
4.
Dynamics of Diaporthe ampelina Conidia Released from Grape Canes that Overwintered in the Vineyard.
Plant Dis
; 105(10): 3092-3100, 2021 Oct.
Artículo
en Inglés
| MEDLINE | ID: mdl-33755509
5.
Production and release of asexual sporangia in Plasmopara viticola.
Phytopathology
; 103(1): 64-73, 2013 Jan.
Artículo
en Inglés
| MEDLINE | ID: mdl-22950738
6.
The Functional Profile and Antioxidant Capacity of Tomato Fruits Are Modulated by the Interaction between Microbial Biostimulants, Soil Properties, and Soil Nitrogen Status.
Antioxidants (Basel)
; 12(2)2023 Feb 19.
Artículo
en Inglés
| MEDLINE | ID: mdl-36830078
7.
A 3-year application of different mycorrhiza-based plant biostimulants distinctively modulates photosynthetic performance, leaf metabolism, and fruit quality in grapes (Vitis vinifera L.).
Front Plant Sci
; 14: 1236199, 2023.
Artículo
en Inglés
| MEDLINE | ID: mdl-37711298
8.
The role of rain in dispersal of the primary inoculum of Plasmopara viticola.
Phytopathology
; 102(2): 158-65, 2012 Feb.
Artículo
en Inglés
| MEDLINE | ID: mdl-21942732
9.
No indication of strict host associations in a widespread mycoparasite: grapevine powdery mildew (Erysiphe necator) is attacked by phylogenetically distant Ampelomyces strains in the field.
Phytopathology
; 102(7): 707-16, 2012 Jul.
Artículo
en Inglés
| MEDLINE | ID: mdl-22512466
10.
Evaluation of a Warning System for Early-Season Control of Grapevine Powdery Mildew.
Plant Dis
; 96(1): 104-110, 2012 Jan.
Artículo
en Inglés
| MEDLINE | ID: mdl-30731854
11.
Development of an online pan-European Integrated Pest Management Resource Toolbox.
Open Res Eur
; 2: 72, 2022.
Artículo
en Inglés
| MEDLINE | ID: mdl-37645315
12.
Development and Validation of a Mechanistic Model That Predicts Infection by Diaporthe ampelina, the Causal Agent of Phomopsis Cane and Leaf Spot of Grapevines.
Front Plant Sci
; 13: 872333, 2022.
Artículo
en Inglés
| MEDLINE | ID: mdl-35463401
13.
Evaluation of Sown Cover Crops and Spontaneous Weed Flora as a Potential Reservoir of Black-Foot Pathogens in Organic Viticulture.
Biology (Basel)
; 10(6)2021 Jun 03.
Artículo
en Inglés
| MEDLINE | ID: mdl-34204894
14.
Dynamics of ascospore maturation and discharge in Erysiphe necator, the causal agent of grape powdery mildew.
Phytopathology
; 100(12): 1321-9, 2010 Dec.
Artículo
en Inglés
| MEDLINE | ID: mdl-21062172
15.
Assessment of Resistance Components for Improved Phenotyping of Grapevine Varieties Resistant to Downy Mildew.
Front Plant Sci
; 10: 1559, 2019.
Artículo
en Inglés
| MEDLINE | ID: mdl-31827485
16.
A network meta-analysis provides new insight into fungicide scheduling for the control of Botrytis cinerea in vineyards.
Pest Manag Sci
; 75(2): 324-332, 2019 Feb.
Artículo
en Inglés
| MEDLINE | ID: mdl-29885027
17.
A Mechanistic Model of Botrytis cinerea on Grapevines That Includes Weather, Vine Growth Stage, and the Main Infection Pathways.
PLoS One
; 10(10): e0140444, 2015.
Artículo
en Inglés
| MEDLINE | ID: mdl-26457808
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