New Tools Help Make Early Detection Of Invasive Species Easier
Since funding, gear and time are limited, scientists often can only sample for invasive species over small fractions of vulnerable areas.
January 30, 2019
Most of the 10,000 ships lost to the bottom of the Great Lakes in wrecks over the past 400 years are still lost – hidden somewhere in 6 quadrillion gallons of water. Finding anything in a lake is a lesson in humility, so life as a freshwater biologist is always humbling. If we can’t account for huge steel freighters, imagine the challenge of finding a single tiny organism.
But it is crucial to detect invasive species as early as possible. Aquatic invasive species cause billions of dollars in economic damages, and regulators base multimillion-dollar management decisions on scientists’ and managers’ ability to detect them. It is much more cost-effective to invest in prevention measures than to react after a species becomes established. And low-density populations are easier to manage than species that have taken over an ecosystem.
But since funding, gear and time are limited, scientists often can only sample for invasives over small fractions of vulnerable areas. Compounding the challenge, our target species tend to lurk at low densities – that is, they are rare in most places.
Invasive species cause enormous ecological and economic harm. As just one example, invasive insects have done some US$13 billion in damage yearly to crops in the United States. But investments in effective and comprehensive invasive species prevention efforts can help prevent future ecological and economic harm by invasive species.
A belated find
I have spent eight years studying the spiny water flea (Bythotrephes longimanus), an invasive zooplankton, in Wisconsin. In a recent study, I worked with my colleagues Eric Pedersen and Jake Vander Zanden to develop a theoretical framework that uses math and computer modeling to improve detection of invasive species at low densities.
Our model provides a simple rule of thumb for designing surveillance programs with no information other than an estimate of expected population densities. In other words, if managers have a ballpark understanding of how many individuals are in a system, our models can provide some basic information about how much effort they need to invest in sampling in order to detect the species reliably. Alternatively, our models can help managers estimate whether their current efforts are effective for detecting populations early in the invasion process.
For us, this challenge was personal. The spiny water flea has upended the food web of our own Lake Mendota in Madison.
In most lakes it’s not surprising to miss new biological invasions. But Lake Mendota is one of the most well-studied lakes in the world, and we sampled it over 200 times in the decade leading up to the flea’s detection.
Zooplankton are tiny organisms: The spiny water flea is less than a half-inch long. To find them, we drag a cone-shaped net through the water. The net is nearly 6 feet long, with a hoop about a foot and a half in diameter at one end and a collection cup that traps captured zooplankton at the other. For every 10 feet that we pull the net through the lake, we sample nearly 160 gallons of water – a quantity that would be a struggle to carry, but represents just one one-billionth of the volume of Lake Mendota.
At first, the spiny water flea’s invasion of Lake Mendota seemed like the simplest of detection challenges. When we first identified its presence in 2009, our nets teemed with pinky-width tail spines and jet-black eye spots. We estimated that these densities would correspond to a lakewide population of trillions.
But as we learned more, we found that the fleas had likely been in the lake for as long as a decade before showing up in masses we referred to as “spiny water flea applesauce” in our collection jars.
Rules of thumb for detecting invasive species
While this realization was a shock, our work revealed that it wasn’t actually surprising. Since invasive species often lurk at low densities, missing invasive populations is more likely the rule than the exception, even in well-monitored ecosystems.
Detecting invasive species is the first step of any management strategy, and early detection is challenging but critical for effectively managing harmful invaders, such as Asian carp and zebra mussels. Failing to detect spiny water flea has been a key stumbling block in managing its spread across the Midwest. Similar dynamics are occurring with other invasive species, including medflies in California and Didymo algae, also known as “rock snot,” which is causing blooms in rivers across North America.
We wanted to see whether there were ways to make detection more effective. To do this, we used theoretical models that explore detection at low densities to provide simple rules of thumb that aim to improve the process.
At low densities, detecting a small invasive organism in a large area can be nearly impossible without extraordinary effort. Even if there were one spiny water flea for every cubic meter of water in Lake Mendota, catching one in a net would be like finding a sesame seed in roughly 250 gallons of water.
However, managers can dramatically improve detection rates by targeting their sampling to areas or time periods when the target species is likely to be present at higher densities. Humans do this naturally when we have the necessary information. For example, I don’t search grocery stores randomly for blueberries – I look in the produce section, mainly in late summer when blueberries are in season in Wisconsin.
The spiny water flea is most abundant in fall. By doubling search efforts in the fall, we calculated that managers would improve detection as much as if they doubled efforts over the entire year.
Targeting is particularly important in multi-species surveys. Managers often look for multiple invasive species when they are sampling, but we concluded in our study that it’s much more efficient to target each species separately if they differ in when or where they are most abundant. And the greater the difference, the greater the benefit from sampling for them separately.
It also helps to identify locations that are vulnerable to invasion. If a manager is tasked with monitoring a dozen lakes, she could either spread effort equally among them or use information about what kinds of lakes the invader tends to invade to target vulnerable lakes. Focusing efforts on a smaller number of vulnerable lakes, instead of sampling all 12, might be enough to overcome the challenges of detecting species at low densities.
Our rules of thumb can help scientists and managers work smarter.
This article was originally published on Jan. 24, 2019 by The Conversation. Jake Walsh is a postdoctoral research assistant at the University of Wisconsin–Madison. Walsh receives funding from the National Science Foundation’s Long-Term Ecological Research Program and the Wisconsin Department of Natural Resources.
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