Details

Autor(en) / Beteiligte

• Yang, Bo
• Hawthorne, Timothy L.
• Aoki, Lillian
• Beatty, Deanna S.
• Copeland, Tyler
• Domke, Lia K.
• Eckert, Ginny L.
• Gomes, Carla P.
• Graham, Olivia J.
• Harvell, C. Drew
• Hovel, Kevin A.
• Hessing‐Lewis, Margot
• Harper, Leah
• Mueller, Ryan S.
• Rappazzo, Brendan
• Reshitnyk, Luba
• Stachowicz, John J.
• Tomas, Fiona
• Duffy, J. Emmett

Titel

Low‐Altitude UAV Imaging Accurately Quantifies Eelgrass Wasting Disease From Alaska to California

Ist Teil von

• Geophysical research letters, 2023-02, Vol.50 (4), p.n/a

Ort / Verlag

Washington: John Wiley & Sons, Inc

Erscheinungsjahr

2023

Link zum Volltext

Quelle

Wiley-Blackwell Journals

Beschreibungen/Notizen

• Declines in eelgrass, an important and widespread coastal habitat, are associated with wasting disease in recent outbreaks on the Pacific coast of North America. This study presents a novel method for mapping and predicting wasting disease using Unoccupied Aerial Vehicle (UAV) with low‐altitude autonomous imaging of visible bands. We conducted UAV mapping and sampling in intertidal eelgrass beds across multiple sites in Alaska, British Columbia, and California. We designed and implemented a UAV low‐altitude mapping protocol to detect disease prevalence and validated against in situ results. Our analysis revealed that green leaf area index derived from UAV imagery was a strong and significant (inverse) predictor of spatial distribution and severity of wasting disease measured on the ground, especially for regions with extensive disease infection. This study highlights a novel, efficient, and portable method to investigate seagrass disease at landscape scales across geographic regions and conditions. Plain Language Summary Diseases of marine organisms are increasing in many regions worldwide, therefore, efficient time‐series monitoring is critical for understanding the dynamics of disease and examining its progression in time to implement management interventions. In the first study of its kind, we use high‐resolution Unoccupied Aerial Vehicle (UAV) imagery collected to detect disease at 12 sites across the North‐East Pacific coast of North America spanning 18 degrees of latitude. The low altitude UAV visible‐bands imagery achieved 1.5 cm spatial resolution, and analysis was performed at the seagrass leaf scale based on object‐oriented image analysis. Our findings suggest that drone mapping of coastal plants may substantially increase the scale of disease risk assessments in nearshore habitats and further our understanding of seagrass meadow spatial‐temporal dynamics. These can be scaled up by searching for environmental signals of the pathogen, for example, with surveillance of wastewater for signs of Covid in human populations. This application could easily apply to other areas to construct a high‐resolution monitoring network for seagrass conservation. Key Points First study using low‐altitude high‐resolution Unoccupied Aerial Vehicle (UAV) imagery to detect coastal seagrass disease The low altitude UAV mapping achieved 1.5 cm spatial resolution and the object‐oriented analysis were performed at the seagrass leaf scale Statistical validation against in situ sampling demonstrated reliable results to use drone imaging for coastal plants disease assessment