Posts Tagged policy

Dec 10 2021

Retraction of Flawed MPA Study Implicates Larger Problems in MPA Science

Source: University of Washington, Sustainable Fisheries
By Max Mossler, UW Sustainable Fisheries Managing Editor
December 9, 2021

Editor’s note: This article was originally published on SustainableFisheries-UW.org, a University of Washington project to better communicate fishery science.

After months of public criticism and findings of a conflict of interest, a prominent scientific paper (Cabral et al. 2020, A global network of marine protected areas for food) was recently retracted by The Proceedings of the National Academy of Sciences (PNAS).

A retraction is a Big Deal in science, especially from a prominent journal. What’s strange in this story is how the conflict of interest intersects with the science. The conflict of interest was apparent immediately upon publication, but it wasn’t until major problems in the underlying science were revealed that an investigation was launched, and the paper eventually retracted.

Cabral et al. 2020 claimed that closing an additional 5% of the ocean to fishing would increase fish catches by 20%. That snappy statistic made for a great headline—the paper was immediately covered by The Economist, Forbes, Anthropocene Magazine, and The Conversation when it was published in October 2020. It made its way through the popular press (the New York Times, Axios, National Geographic, and The Hill have all cited the paper)—and eventually into the U.S. congressional record: It was submitted as supporting evidence for a bill by then-Representative Deb Haaland, now the Secretary of the Interior. Cabral et al. 2020’s Altmetric Attention Score, a measure of how widely a scientific paper is shared, is in the top 5% all-time.

But with increased press comes increased scrutiny. Several close collaborators of the Cabral et al. group wrote scientific critiques that PNAS published earlier this year. The critiques pointed out errors and impossible assumptions that strongly suggested the paper was inadequately peer reviewed.

PNAS later determined that the person responsible for assigning Cabral et al.’s peer reviewers, Dr. Jane Lubchenco, had a conflict of interest. She collaborated with the Cabral et al. group and was the senior author on a follow-up paper published in Nature in March 2021. That follow-up paper, Sala et al. 2021, included the authors of Cabral et al. and depended on the same MPA model meant to be reviewed in PNAS.

Shortly after the Nature paper was published, Dr. Magnus Johnson (of the University of Hull in the U.K.) wrote a letter to the editor-in-chief of PNAS reporting the conflict of interest; an investigation was launched, and PNAS decided to retract Cabral et al. 2020 on October 6th, 2021—nearly a year from its original publication.

According to the editor-in-chief of PNAS, the frequent collaboration relationship Lubchenco had with the authors constituted a conflict of interest, as did the personal relationship with one of the authors, Dr. Steve Gaines—her brother-in-law. She should not have accepted the task of editing the paper. These conflicts of interest were clear and apparent from the time Cabral et al. 2020 was first submitted, but it wasn’t until the follow-up paper, Sala et al. 2021, received more press than any other ocean science paper in recent memory that eyebrows were raised.

Now the Sala et al. follow-up paper is being questioned—more potential inaccuracies have been found.

A highly flawed computer model with poor assumptions

Cabral et al. 2020 assembled a computer model out of several kinds of fishery data to predict where marine protected areas (MPAs) should be placed to maximize global sustainable seafood production. The model produced the map below, where the areas in green are high priority for MPAs and the orange areas are low priority.

Figure 2a from the now retracted Cabral et al. 2020, A global network of marine protected areas for food.

MPAs meant to increase food production do so by reducing fishing pressure in places where it is too high (overfishing). Asia and Southeast Asia have some of the highest overfishing rates in the world—reducing fishing pressure there is a no-brainer, but the model determined many of those areas to be low priority for protection.

The map above (Figure 2a from the retracted paper) should have been a big red flag for the peer reviewers of Cabral et al. 2020. Why were MPAs prioritized all around the U.S., where overfishing has been practically eliminated, but not prioritized around India, Thailand, Indonesia, Malaysia, Vietnam, and China?

Clearly, something was wrong with the model.

Several researchers with a long history of collaboration with the Cabral et al. authors noticed the oddity in the MPA prioritization and pointed out a fundamental issue: the model contained biologically impossible assumptions. It assumed that unassessed fish populations were globally linked—in the model, their geographic ranges could stretch across multiple oceans and their growth rates were based on global data rather than more-precise local data.

An “unassessed” fish population means there is no consistent scientific assessment of its status. Data on those fisheries is sparce. They comprise about half of the world’s catch with the other half monitored and assessed. In monitored or assessed fisheries, all kinds of data are consistently collected and stored in the RAM Legacy Database.

With little data, uncertainty about the future of unassessed fish stocks requires assumptions to be made. But the need for assumptions doesn’t excuse impossible ones. The model in Cabral et al. assumed unassessed fish populations could travel and mate across the species’ entire range rather than just within the population. This is akin to assuming North Sea Atlantic cod could interact with Gulf of Maine Atlantic cod who live over 3,000 miles away. There were cases in the model that assumed MPAs in the Atlantic would benefit fish in the Pacific.

Cabral et al. also assumed density dependence was global rather than local or regional, meaning recruitment of new fish to a population (basically a birthrate) depended on its global abundance rather than local abundance. In reality, density dependent effects are only relevant to the specific population of a particular species, e.g. North Sea cod versus all Atlantic cod; the abundance of North Sea cod has no relation to the abundance of Gulf of Maine cod despite being the same species.

The first critique pointing out issues with the model was published in April by Ray Hilborn (founder of this site). Another critique by Dan Ovando, Owen Liu, Renato Molino, and Cody Szuwalski (all of whom did their Ph.D.’s or a postdoc with members of the Cabral et al. group) expanded on Hilborn’s critique by digging into the math. They found that, due to the assumption that species were connected globally, Cabral et al.’s model overestimated the geographic range of unassessed fish by a factor of seventeen, compared to the scientifically assessed stocks.

Perhaps because it is biologically impossible, there is little precedent for modeling the dynamics of a species as one globally connected population. However, there is precedent for modeling unassessed fish populations at regional scales. Hilborn, Ovando, Szuwalski, Cabral, and many other authors of Cabral et al. 2020 were all authors on Costello et al. 2016Global fishery prospects under contrasting management regimes, a seminal paper that modeled the range of unassessed fisheries on a regional scale. The authors of Cabral et al. 2020 had a path to follow from Costello et al. 2016, but changed assumptions.

Data errors
Since the authors of the Ovando et al. critique had been intimately involved in the Costello et al. 2016 paper, they were uniquely capable of looking at and interpreting the code for Cabral et al. They found two major errors:

1. Cabral et al. inadvertently created and used incorrect estimates of fishing mortality for the world’s assessed fisheries. This resulted in an overestimation of the amount of food benefits that MPAs could produce, and the size of MPAs that would produce those benefits. This error also contributed to the map that incorrectly prioritized areas with good fisheries management for MPA implementation; and

2. They mistakenly included a large (~3 million metric tons) and nonexistent stock from an outdated version of the RAM legacy database. They also placed this stock in the wrong ocean for their analysis.
Ovando et al. corrected the coding errors and reran the analysis. They found that the proposed benefits of MPAs for food decreased by 50% but still produced strange results.

Ovando et al. note (emphasis added):

“Using the corrected [model], Cabral et al.’s food-maximizing MPA network would close 22% of the United States’ exclusive economic zone (EEZ) to fishing, yet places only 2.5% of India’s, 10% of Indonesia’s, and 12% of China’s EEZs in MPAs… the median F/FMSY (fishing mortality rate F relative to the fishing mortality rate producing maximum sustainable yield FMSY) of fisheries in India, Indonesia, and China is nearly twice that of the United States, creating almost 5 times as much potential food upside from fishery reforms in those regions relative to the United States.”

In their response to Ovando et al., the authors of Cabral et al. acknowledge the model is not particularly realistic:

“The key assumption we made—that populations are well mixed throughout their geographic range—is indeed a heroic one.”

However, in their retraction note, the authors maintain that their conclusions are valid and intend to resubmit the paper.

Connection to Sala et al. 2021
Their persistence may be tied to Sala et al. 2021, Protecting the global ocean for biodiversity, food, and climate, the prominent follow-up paper published this past March in Nature. It presents several computer models that predict that an increase in MPAs to reduce fishing has benefits for biodiversity, food production, and carbon emissions. The food provisioning MPA model used by Sala et al. 2021 is the same one as Cabral et al. 2020 and was justified based on the results of the now-retracted paper.

Indeed, all the Cabral et al. 2020 authors were authors on the Sala et al. paper, including the first four authors of the Sala paper (authors are generally ordered in order of contribution, except for the “senior author,” who is the last listed). The Sala et al. paper was the most prominent ocean science paper of the year with an Altmetric score 4x higher than Cabral et al. 2020—it was covered in nearly every major newspaper in North America and Europe.

The acknowledged outright errors from Cabral et al. 2020 were corrected in the Sala et al. paper, but the biologically impossible assumptions that unassessed fish can travel across oceans, and that density dependence is global rather than local, remain.

The same authors from the Ovando et al. critique of the Cabral paper have responded to the Sala et al. paper, demonstrating that Sala et al.’s estimates of the effects of a global MPA network on food production were unreliable.

In the original Cabral et al. critique, the Ovando et al. authors argue that “omitting distance from MPA models produces results that are not credible.” Before it was retracted, the Cabral et al. authors responded saying their results were “a useful starting point.”

However the Ovando et al. critique of Sala et al. shows why that isn’t true:

Instead of just arguing the assumptions were poorly chosen, the recent Ovando et al. re-ran Sala et al.’s analysis with the assumption that fish stay in their region (defined by the U.N. FAO) and are dependent on local factors (the same, more realistic assumptions from Costello et al. 2016 that they all worked on together and that both Cabral et al. 2020 and Sala et al. 2021 were based on).

“By changing only two assumptions made by Sala et al. 2021 to different and equally if not more plausible assumptions, we produced a starkly different picture of the magnitude of potential food benefits from MPAs, and the location of priority areas for MPAs designed around food security.”

Costello et al. 2016 set a reasonable standard for evaluating unassessed fish stocks. That paper assumed fish live in their FAO region and are dependent on local abundance for population growth rates—about the best assumptions you can make about unmonitored fish populations given available data.

Sala et al. and Cabral et al. modified those assumptions to say that unassessed fish stocks are interconnected around the world and depend on global ecology for population growth rates. Why do this when more realistic assumptions are available and had been previously used by the authors? Both the Cabral and Sala papers used values from the Costello et al. paper as the basis for the model then changed the assumptions to less plausible ones.

Peer review was flawed – how much was due to the conflict of interest?
Cabral et al. clearly suffered from an inadequate peer review. An appropriately thorough reviewer would have seen the map of proposed MPAs, wondered why MPAs were prioritized in the U.S. but not overfished regions in Asia, and pushed the authors to explain why the map seemed “off.” Catching the coding errors would be a difficult task; perhaps only those who contributed to the original code on the earlier Costello et al. paper could have found them, but scrutinizing the map and clarifying the assumptions should have been primary, first principle peer-reviewing steps that should have led to the discovery of errors.

So how did Cabral et al. end up in PNAS, one of the most prestigious journals in the field, then get reproduced in Nature in the most covered paper of the year? The first decision was made by the editors at PNAS who read the paper, thought it was worthy of consideration, then assigned an individual PNAS editor to dive deeper and find peer-reviewers for it. In this case, the editor assigned to Cabral et al. was Dr. Jane Lubchenco, the former NOAA administrator and notable MPA scientist and advocate. She would make perfect sense as a choice to edit and find reviewers for MPA models, but she had a conflict of interest:

Cabral et al. was submitted to PNAS on January 6th, 2020. Notably, the Sala et al. paper was submitted to Nature two weeks prior, on December 19th, 2019. The senior author on the Sala et al. paper was Jane Lubchenco. She should not have been allowed to submit the Sala paper alongside other authors and then assign reviewers for a fundamental part of the paper two weeks later. Her brother-in-law, Dr. Steve Gaines, was also an author on both papers—familial relationships are another conflict of interest.

The editor in chief of PNAS told Retraction Watch both conflicts of interest would have been enough for retraction, even “absent the data errors.”

It will be interesting to see where the Cabral paper is resubmitted and how it is reviewed.

More scrutiny of the other models presented in Sala et al. 2021
You probably saw a headline covering Sala et al. 2021. Most of the press focused on its carbon model that concluded, Bottom Trawling Releases As Much Carbon as Air Travel. Most of the headlines were almost certainly not true.

The carbon model was the first attempt to quantify the global climate change impact of bottom trawling, a type of fishing in which nets are dragged along the seafloor. Bottom trawling kicks up sediment; the researchers tried to figure out how much carbon stored in sediment is redissolved into seawater due to trawling disturbances. More carbon dissolved in seawater means less atmospheric carbon can be absorbed by the ocean, contributing to climate change. Carbon dissolved in seawater also causes ocean acidification.

Sala et al. claimed their carbon model is a “best estimate,” but other scientists disagree and are have pointed out issues in the model that echo the same problems with the Cabral et al. model: impossible assumptions.

A response from Hiddink et al. noted one of the carbon model’s untrue assumptions: that sediment is inert until disturbed by trawling. According to Hiddink et al., this ignores “decades of geochemical research on natural processing of [carbon] in marine sediments.” There are many sea creatures that burrow in the seafloor—nearly all of them cycle carbon back into seawater (most organisms, like humans, respirate carbon).

Hiddink et al. also claim that the Sala et al. model greatly overestimated the amount of sediment that is disturbed: The model assumed all the sediment in the penetration depth is resuspended in the water column, whereas “field observations show that trawling resuspends only [~10%].”

Hiddink et al. say the Sala et al. model overestimates carbon impacts by an order of magnitude or more.

Was this another case of inadequate peer-review? An order of magnitude or more is a substantial error.

The carbon and food models weren’t the only ones with questionable assumptions. The biodiversity model in Sala et al. claimed that with increased MPAs, ocean biodiversity would increase. This is undoubtedly true inside an MPA, but the model assumed fishing rates remain constant outside the proposed MPAs, meaning effort that was inside the MPA disappears, rather than moving elsewhere. This is in direct conflict with the assumptions of the food provision model presented in their primary results which assumed the effort from inside the MPA moved elsewhere.

Not only is this picking and choosing MPA assumptions to present; in real life, this is rarely what happens. When fishermen are told they can’t fish in a particular area, they generally fish harder in other areas. Assuming fishing rates remain the same outside of MPAs probably exaggerates the practical benefits of MPAs for biodiversity.

The picking and choosing of model assumptions in Sala et al. has drawn yet another critique by Hilborn and Kaiser (not yet published on a preprint server). Sala et al. 2021 did report consistent fishing pressure assumptions in secondary results and supplementary materials, however those were not part of the main paper.

When asked about the status of the three known responses to Sala et al. (Ovando et al., Hiddink et al., and Hilborn & Kaiser), Nature had no comment as the review process is confidential.

Predictions need more scrutiny and less press
Regardless of any conflict of interest, the science in both Cabral et al. and Sala et al. is critically flawed, but being used to advocate for public policy. Both follow a recent trend of publishing predictions that use a limited set of assumptions (in a very uncertain world) to produce global maps that get published in high-profile journals and garner considerable media and political attention.

Computer models are essential tools for science and management, but the accuracy of their predictions depends on both the quality of the data and the assumptions they are based on. Often, a problem is so complex that several assumptions may be equally plausible; readers need to be made aware when different assumptions lead to vastly different outcomes.

The Cabral et al. and Sala et al. papers disregard uncertainty in favor of set values for their model parameters. They don’t account for the enormous uncertainty in these parameters and don’t provide strong evidence that their choice of values was correct. The assumptions and parameters produce big headlines, but are fundamentally unhelpful for the future of ocean governance and sustainability. We expect policy-makers and resource managers to make decisions based on the best available science. Inconsistent and unrealistic assumptions are not that.


Original post: https://www.seafoodnews.com/Story/1214154/Retraction-of-Flawed-MPA-Study-Implicates-Larger-Problems-in-MPA-Science

Posted with permission.

Feb 26 2019

Environmental Impact Displacement in Fisheries & Food

A recent policy perspective paper in Conservation Letters, Lewison et al. 2019 (open access), summarized several examples of environmental impact ‘displacement,’ an important policy concept with implications for fisheries and food.

Examples of environmental impact displacement

Environmental impact displacement is when a conservation policy designed to reduce impact in one area, displaces it to another area, sometimes making the overall problem worse. Researchers cite sea turtle bycatch in swordfish fisheries as an example of displacement in fisheries: U.S. Pacific swordfish fishing was curtailed to protect sea turtles caught as bycatch. However, lower U.S. catch increased foreign swordfish demand which ended up killing more sea turtles as foreign swordfish fisheries had higher rates of bycatch.

ProPublica and the New York Times recently published a long exposé about how a U.S. policy meant to reduce carbon emissions (by increasing biofuel use) raised demand for palm oil in Southeast Asia, which actually increased emissions and jumpstarted the palm oil/biodiversity crisis (this example is also cited in Lewison et al.).

The viral Ocean Cleanup Project is another example of environmental displacement; the crowdfunded campaign was trying to remove marine debris from the great Pacific garbage patch by sweeping a giant net-like object across the ocean. However, if it had worked as intended (it broke), it would have killed many more organisms than the trash it was trying to remove from the ocean.

Environmental displacement in fisheries & food

The concept of environmental impact displacement is important to consider in fisheries management and marine conservation. The swordfish case above is a good example of displacement in individual fisheries, but there are other areas of fishery management that should consider environmental impact displacement. For example, no-take marine protected areas often increase fishing pressure outside the area being protected, nullifying the protection. In some cases, displacing fishing pressure benefits the ecosystem, but often it does not.

Zooming out in scale raises larger systemic questions about food: Consider fisheries and marine conservation as part of a broader, global system of food and ecological preservation. A legitimate argument can be made that fulfilling fishery potential and consuming more seafood is good for the planet—it provides low-carbon, low-impact protein.

As the developing world continues to acquire wealth, global demand for animal-protein will continue to rise. The more seafood that is eaten in place of cow, the better, since bovine farming is the largest driver of rainforest and biodiversity loss on the planet. Not only is seafood the lowest-impact animal protein, several kinds of seafood (e.g. farmed bivalves and wild-caught pelagics) are among the lowest impact foods of any kind.

Solutions to environmental displacement

Lewison et al. 2019 outline ways to reduce environmental impact displacement that can be applied to fisheries management and global food systems. The first step, researchers state, is explicitly considering displacement in policy design, scoping, and evaluation. Fishery managers should evaluate and understand the biological, economic, and social outcomes of proposed policies to avoid issues like accidentally increasing turtle bycatch across the world or raising fishing pressure in an area surrounding an MPA.

Other ways to avoid displacement include:

  • Think large-scale to consider all economic/biological/social relationships
  • Enact both demand-side and supply-side policies
  • International trade agreements and cooperation as a holistic approach to global conservation

Conservation groups should consider the global food system and environmental impact displacement in their advocacy; policy makers and natural resource managers should consider environmental impact displacement in their decision-making processes. Conservation will be more effective with a larger, broad approach—particularly with fisheries and food. Lewison et al. 2019 is open access and available here.


Original post: https://sustainablefisheries-uw.org/environmental-impact-displacement/

Nov 22 2012

Sea Otters likely to be legislative focus for Unted Fisherman of Alaska this year

Sea otters and the Arctic are two focal points for Alaska’s top fishing group at both state and federal policy levels.

United Fishermen of Alaska is the nations largest industry trade group representing nearly 40 organizations. At its recent annual meeting UFA outlined several of its policy watches prior to the legislative session; the group also gave out awards and made a job offer.

UFA is working closely with state and federal overseers to craft a management plan for exploding populations of sea otters in Southeast Alaska. The mammals, which were reintroduced to the region in the 1950s, are feasting on fishermen’s shellfish catches and completely wiping out stocks in prime areas. Sea otters are protected under the Endangered Species Act and may only be hunted by Alaska Natives for traditional uses.

“I think there are opportunities for Alaska Natives to more readily use sea otters in their art, and there also is the need for a management plan,” said UFA executive director Mark Vinsel.  “One thing that is lacking in the US policy is consideration for exploding species. That is a situation that all parties see happening here with sea otters in Southeast Alaska.”

Read the full article at SEAFOOD.COM

 

Nov 8 2012

National ocean policy sparks partisan fight

 Partisan battles are engulfing the nation’s ocean policy, showing that polarization over environmental issuesdoesn’t stop at the water’s edge.For years, ocean policy was the preserve of wonks. But President Obama created the first national ocean policy, with a tiny White House staff, and with that set off some fierce election-year fights.

 Conservative Republicans warn that the administration is determined to expand its regulatory reach and curb the extraction of valuable energy resources, while many Democrats, and their environmentalist allies, argue that the policy will keep the ocean healthy and reduce conflicts over its use.

The wrangling threatens to overshadow a fundamental issue — the country’s patchwork approach to managing offshore waters. Twenty-seven federal agencies, representing interests as diverse as farmers and shippers, have some role in governing the oceans. Obama’s July 2010 executive order set up a National Ocean Council, based at the White House, that is designed to reconcile the competing interests of different agencies and ocean users.

Apr 5 2012

Federal Government Holds Hearing on the National Ocean Policy’s Effect on Fishing

On March 22, 2012, the House Natural Resources Subcommittee on Fisheries, Wildlife, Oceans & Insular Affairs held an oversight hearing titled Empty Hooks: The National Ocean Policy is the Latest Threat to Access for Recreational and Commercial Fishermen. 

During that hearing, George Mannina testified on exactly what policy decisions are having on fishing in the United States. See his testimony below:


Testimony of George J. Mannina, Jr.

 

Before the Subcommittee on Fisheries, Wildlife, Oceans, and Insular Affairs Regarding National Ocean Policy

March 22, 2012

Mr. Chairman and distinguished members of this Subcommittee, I am pleased to be here today.  I was privileged to serve as Counsel to this Subcommittee for eight years prior to becoming the Chief Counsel and Staff Director for the Republican members of the House Merchant Marine and Fisheries Committee before it was merged into the Committee on Natural Resources.  During my years with the Subcommittee and Committee, and since that time, I have worked on numerous ocean policy issues.  I am testifying today in my individual capacity and not on behalf of any client or of my firm, Nossaman LLP, although one of our associates, Audrey  Huang, has worked with me on this testimony.

Read Mannina’s full testimony here

 

 
Jan 28 2012

LITTLE FISH, BIG INDUSTRY: Proposed Restrictions on the Menhaden Industry Threaten Atlantic Coastal Economies

 

Just as scientists note the complex interdependence of species in the natural world, economists note a similar kind of interdependence at work with industries, communities, and livelihoods. With so much already on the line during these trying times, menhaden policies based on disputed, inconclusive ecological theories could yield devastating impacts on this economic web of life. 

 

With an economy struggling to regain equilibrium, governments at all levels have adopted policies aimed at triggering a resurgence in job growth and economic stimulus. Unfortunately, the prospect of some new policies may create more challenging conditions for one important industry based on a small and prolific fish – the Atlantic menhaden.

Most Americans know little about menhaden, an oily fish more likely to be found in their medicine cabinets than on their dinner plates. Prized as one of the main sources for fish oil and fish meal, menhaden are also found in hundreds of household items, from margarine to pet food to salad dressing. The fish also make great bait for crabbers and lobstermen. All told, the resource supports thousands of jobs – directly and indirectly – and generates hundreds of millions of dollars annually, in effect, representing a significant path towards improving the country’s dour economic circumstances.

But this path may become fraught with obstruction, which largely stems from disagreement about the sustainability of the fish and mounting pressure on the regulatory authority that oversees its management. Lauded as a victory for environmental and recreational angling groups who have long dismayed of commercial menhaden fishing, the Atlantic States Marine Fisheries Commission (ASMFC), a deliberative body of representatives from all 15 Atlantic coast states, recently voted to set new “safe harvest” limits on menhaden. Before they are implemented, the ASMFC Menhaden Board – a committee comprised of state fisheries professionals and political appointees – will need to determine the regulations that will achieve these newly approved goals.  The question is: will they implement policies that cause economic harm to the industry and, consequently, the myriad jobs and communities that rely on it?

 

Read the rest of the article on Saving Seafood.