Brett Hobson scite author profile

Environmental DNA (eDNA) can be used to identify macroorganisms and describe biodiversity, and thus has promise to supplement biological monitoring in marine ecosystems. Despite this promise, scaling sample acquisition to the spatial and temporal scales needed for effective monitoring would require prohibitively large investments in time and human resources. To address this challenge, we evaluated the efficacy of an autonomous eDNA sampling system and compare results obtained to traditional eDNA sampling methods. The autonomous sampling instrument consisted of the Environmental Sample Processor (ESP) coupled to an autonomous underwater vehicle (AUV). We tested equivalency between the ESP and traditional eDNA sampling techniques by comparing the quantification of eDNA across a broad range of taxa, from microbes (SAR11), phytoplankton (Pseudo-nitzschia spp.), and invertebrates (krill: Euphausia pacifica) to vertebrates (anchovy: Engraulis mordax). No significant differences in eDNA densities were observed between the two sample collection and filtration methods. eDNA filters collected by the ESP were preserved and stable for 21 days, the typical deployment length of the instrumentation. Finally, we demonstrated the unique capabilities of an autonomous, mobile ESP during a deployment near Monterey Bay, CA, by remotely and repeatedly sampling a water mass over 12 h. The development of a mobile ESP demonstrates the promise of utilizing eDNA measurements to observe complex biological processes in the ocean absent a human presence.

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Tethys-class long range AUVs - extending the endurance of propeller-driven cruising AUVs from days to weeks

Hobson

Bellingham

Kieft

et al. 2012

113

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Climate Variability and Change: Response of a Coastal Ocean Ecosystem

Chávez¹,

Mbari²,

Pennington³

et al. 2017

Oceanog

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Docking Control System for a 54-cm-Diameter (21-in) AUV

McEwen

Hobson

McBride

et al. 2008

IEEE J. Oceanic Eng.

169

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Efficient propulsion for the Tethys long-range autonomous underwater vehicle

Bellingham

Zhang

Kerwin

et al. 2010

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The Tethys autonomous underwater vehicle (AUV) is a 110 kg vehicle designed for longrange, high-endurance operations. Performance goals include supporting a payload power draw of 8 W for a range of 1000 km at 1 m/s, and a power draw of 1 W for 4000 km at 0.5 m/s. Achieving this performance requires minimizing drag and maximizing propulsion efficiency. In this paper, we present the design of the propulsion system, explore the issues of propeller-hull interactions, and present preliminary test results of power consumption and efficiency. In recent underwater experiments, the propulsion system's power consumptions were measured in both Bollard pull tests and during the vehicle's flights. Preliminary results of power consumptions and efficiency are shown to be close to the theoretical predictions.

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Brett Hobson

In situ Autonomous Acquisition and Preservation of Marine Environmental DNA Using an Autonomous Underwater Vehicle

Tethys-class long range AUVs - extending the endurance of propeller-driven cruising AUVs from days to weeks

Climate Variability and Change: Response of a Coastal Ocean Ecosystem

Docking Control System for a 54-cm-Diameter (21-in) AUV

Efficient propulsion for the Tethys long-range autonomous underwater vehicle

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