Abstract
Invertebrate biodiversity remains poorly understood although it comprises much of the terrestrial animal biomass, most species and supplies many ecosystem services. The main obstacle is specimen-rich samples obtained with quantitative sampling techniques (e.g., Malaise trapping). Traditional sorting requires manual handling, while molecular techniques based on metabarcoding lose the association between individual specimens and sequences and thus struggle with obtaining precise abundance information. Here we present a sorting robot that prepares specimens from bulk samples for barcoding. It detects, images and measures individual specimens from a sample and then moves them into the wells of a 96-well microplate. We show that the images can be used to train convolutional neural networks (CNNs) that are capable of assigning the specimens to 14 insect taxa (usually families) that are particularly common in Malaise trap samples. The average assignment precision for all taxa is 91.4% (75%-100%). This ability of the robot to identify common taxa then allows for taxon-specific subsampling, because the robot can be instructed to only pick a prespecified number of specimens for abundant taxa. To obtain biomass information, the images are also used to measure specimen length and estimate body volume. We outline how the DiversityScanner can be a key component for tackling and monitoring invertebrate diversity by combining molecular and morphological tools: the images generated by the robot become training images for machine learning once they are labelled with taxonomic information from DNA barcodes. We suggest that a combination of automation, machine learning and DNA barcoding has the potential to tackle invertebrate diversity at an unprecedented scale.
Highlights
Biodiversity science is currently at an inflection point
Biodiversity loss had been mostly an academic concern, many biologists had already predicted that the decline would eventually threaten whole ecosystems (May, 2011)
We are at this stage, which explains why the World Economic Forum considers biodiversity loss as one of the top three global risks based on likelihood and impact for the 10 years (World Economic Forum‘s Global Risk Initiative 2020)
Summary
Biodiversity science is currently at an inflection point. For decades, biodiversity loss had been mostly an academic concern, many biologists had already predicted that the decline would eventually threaten whole ecosystems (May, 2011). Well-trained convolutional neural networks (CNNs) would be important because they could use images to (a) identify specimens to species, (b) provide specimens for follow-up research (e.g., microbiome), (c) yield precise abundance information and (d) measure biomass All this would enable semi- automated biomonitoring of invertebrates when samples obtained from the same place at different times are processed. The specimen camera (C2) is a Ximea MQ013CG-E2 using a telecentric Lensation TCST-10-40 lens with a magnification of 1× This camera is moved by the x- and y-axes of the robot to a position above the insect to take a detailed image for the purpose of classification and measuring size (Figures 4 and 7). The robot only sorts insects belonging to a predefined class
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
