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Turtle excluder device

A turtle excluder device () is a rigid or flexible grid installed in the extension panel of a bottom trawl net, primarily used in fisheries, that physically blocks large animals such as sea turtles from entering the cod end while allowing smaller target species like to pass through the bars and be retained. TEDs emerged from collaborative research by NOAA Fisheries and the shrimp industry in the late 1970s to address excessive bycatch in trawl nets, which contributed significantly to strandings and mortality of like loggerheads and Kemp's ridleys. Early prototypes faced challenges with retention, showing losses of 15-30%, but iterative designs in the 1980s improved performance, leading to U.S. federal regulations mandating their use in coastal and offshore trawls by 1987, with subsequent refinements for deeper waters and juvenile turtles. Empirical tests indicate that compliant TED installations exclude up to 97% of sea s from trawls, substantially reducing -related drownings, though effectiveness depends on proper installation and turtle size relative to bar spacing. Shrimpers have reported economic concerns, including costs and verified shrimp catch reductions averaging 6% in offshore operations, prompting ongoing debates over compliance and incentives despite overall net benefits for turtle populations.

History and Development

Early Research and Invention (1970s-1980s)

In the mid-1970s, extensive strandings of loggerhead (Caretta caretta) and Kemp's ridley (Lepidochelys kempii) sea turtles along the southeastern U.S. coast, attributed to drowning in trawl nets, highlighted the need for mitigation measures. These empirical observations, combined with the species' listings as endangered or threatened under the , prompted the (NMFS) to begin research in 1976 on devices to exclude turtles from trawls while preserving catch. Early efforts focused on first-generation barrier panels: a 1978 "forward barrier" achieved only 30% turtle exclusion but caused 38-53% loss, leading to its abandonment; a 1979 "reverse barrier" improved to 79% exclusion yet still resulted in 15-30% reduction and structural failures, prompting discontinuation in 1981. The breakthrough came in 1980 with the invention of the rigid-grid () by gear specialists John Watson and Toomer, drawing from a "jellyball " concept used to eject from nets. This prototype consisted of a steel-framed , exceeding 1 in volume and weighing 97 pounds, with 6-inch (15 cm) bar spacing slanted at 45 degrees inside the trawl codend to deflect toward a top escape opening while permitting passage . Initial tests yielded 89% turtle exclusion with negligible target loss, validating the design's causal mechanism of size-based separation. Field trials commenced in 1981 across and Atlantic waters from to , incorporating refinements like a top-opening escape flap (boosting exclusion to 97%) and an accelerator funnel to enhance flow (increasing catch by 7%). These tests confirmed basic functionality without significant yield reductions on key grounds, spurring iterative : by 1982, the grid was scaled to 1 for twin-rig trawls; 1983 introduced lighter plastic and fiberglass variants; and 1984-1985 yielded compact models (e.g., 42-inch frame) and a "Mini-TED" for inshore use, maintaining 95% exclusion. Such prototypes emphasized empirical validation through controlled releases of captive , prioritizing hydrodynamic efficiency over regulatory mandates.

Regulatory Implementation and Initial Resistance (1980s-1990s)

In 1987, the (NMFS), under the authority of the Act (ESA), promulgated regulations mandating the use of turtle excluder devices (TEDs) in shrimp trawls operating in the inshore and offshore waters of the and South Atlantic to mitigate sea turtle bycatch. These rules stemmed from biological opinions identifying shrimp trawling as a primary cause of sea turtle strandings and mortality, requiring TED installation by specified dates in 1988 for certain vessels. However, implementation faced immediate pushback from the shrimp industry, which argued that TEDs reduced shrimp catches by 10-20% through escape losses and operational inefficiencies like net clogging with debris. To address these concerns, NMFS launched a comprehensive TED Evaluation Program on March 5, 1988, collaborating with participants to compare shrimp catch rates between TED-equipped and standard nets across the and South Atlantic from March 1988 through July 1989. The evaluation, involving paired tows and statistical analysis, found no detectable differences in yields for and shrimp fisheries, contradicting claims of significant economic harm and attributing perceived losses to factors like inconsistent towing practices rather than TEDs themselves. Despite this evidence, shrimpers continued demonstrations and lobbied for delays, citing real disruptions such as increased clogging in turbid waters, which prompted temporary exemptions and design modifications like adding accelerator funnels to improve flow. Federal court battles intensified in 1989, with environmental groups suing NMFS to enforce TED requirements amid non-compliance rates exceeding 50% in some areas, while industry lawsuits challenged the regulations on economic grounds under the . A key compromise emerged from a May 1989 court order mandating offshore TED use, but widespread protests—including vessel flotillas to —led to a temporary moratorium on enforcement until approved TED designs were certified, averting immediate shutdowns but fostering black-market adaptations like partially sealed escape openings to retain more catch. By late 1989, regulations solidified for offshore trawlers, though inshore exemptions persisted, setting precedents for ongoing compliance monitoring amid persistent skepticism from fishermen who viewed TEDs as federally imposed burdens without commensurate turtle population recoveries.

Technical Design and Operation

Core Mechanism and Components

A turtle excluder device (TED) comprises a rigid grid of bars mounted within the aft extension section of a trawl net, positioned immediately ahead of the end to intercept larger marine animals while permitting smaller target species to proceed. The grid, typically framed in rectangular or trapezoidal configurations constructed from or aluminum bars, spans the net's cross-section and is sewn or lashed into place to align with the trawl's tapering , thereby preserving hydrodynamic and minimizing disruptions during towing. The grid bars are spaced 4 inches apart, allowing and finfish under this dimension to pass through apertures into the cod end via forward water currents generated by the trawl's motion, while broader-bodied animals contact the bars and are deflected laterally or upward depending on the grid's . Installed at an of 45 to 55 degrees relative to the net's longitudinal axis, the leverages trawl-induced water dynamics to guide deflected organisms toward an escape opening, often at the top or bottom, where their or active swimming facilitates egress. An escape flap, fashioned from flexible netting or rubber panels, covers the opening and attaches along three sides to the , enabling one-way passage through elastic deformation under pressure from exiting animals before hydrodynamic forces reseal it against the frame to curtail target species egress. Single-grid setups predominate for simplicity, though reinforced variants incorporate double grids or additional hoops to enhance structural integrity against net stresses and debris impacts, ensuring sustained alignment during prolonged hauls. tank validations confirm that such configurations integrate with trawl hydrodynamics by channeling water volume past the grid without excessive , predicated on the causal interplay of net velocity, bar obstruction, and fluid momentum directing size-selective exclusion.

Design Variations and Adaptations

Turtle excluder devices (TEDs) evolved through NMFS-led flume tank and at-sea trials in the 1980s and 1990s, yielding rigid grid-based designs constructed from or aluminum bars for structural integrity and soft mesh-based alternatives using flexible . Rigid TEDs, such as the Super Shooter model featuring an angled aluminum frame in sizes up to 42 by 51 inches, were engineered to deflect turtles outward via a sloped barrier, while soft designs like the Morrison TED employed a conical to guide exclusion without a rigid frame. Specialized rigid variants addressed specific exclusion challenges, including the Georgia Jumper, a frameless oval steel rod grid sewn directly into the net at a 45-degree angle, developed by Georgia shrimper Sinkey Boone to accommodate turtles attempting to jump or maneuver upward. The Anthony Weedless TED incorporated a streamlined to resist debris clogging, and extensions like trash-release panels were integrated into rigid grids during NMFS tests to divert non-target without compromising the core deflector. Soft variants, such as the Taylor TED with larger escape openings, adapted webbing mesh sizes (e.g., 6-inch panels) for flexibility in tapered nets. Adaptations for varying net configurations emerged from empirical testing, with larger grid dimensions (e.g., Super Shooter variants scaled for Gulf twin trawls) suited to deeper-water operations and smaller mini-TEDs (two-thirds scale) fitted to inshore nets to match reduced codend diameters. simulations and field trials in locations like refined these for net depth and size, ensuring angular positioning (typically 25-55 degrees) to optimize deflection paths across trawl types without altering basic grid mechanics. Rigid frames maintained form under in larger or deeper setups, whereas soft cones minimized hydrodynamic in shallower or faster-towed configurations.

Effectiveness and Empirical Evidence

Turtle Exclusion Performance

Current turtle excluder device (TED) designs certified for use in trawls exclude at least 97% of s that enter the net, as determined through standardized testing protocols established by the (NMFS). This efficacy threshold, derived from video-monitored trials releasing loggerhead (Caretta caretta) and Kemp's ridley (Lepidochelys kempii) turtles in front of trawl nets, ensures turtles contact the grid and escape via the escape opening before reaching the cod end. Field evaluations, including those conducted in the U.S. Southeast Atlantic and , confirm these rates for subadult and adult turtles of these species under operational conditions. Exclusion performance varies with biological and operational factors, including turtle size and behavior. Larger , typically those exceeding the grid bar spacing (e.g., 28-inch or 71 cm openings), exhibit higher escape success due to greater strength and maneuverability to push against the grid and exit through the flap. Smaller juveniles may occasionally pass through the grid but face elevated mortality risks if not excluded promptly. Tow duration also affects outcomes indirectly; while TEDs enable escapes regardless of tow length, regulations permit up to 90-minute tows as an alternative to TEDs for smaller vessels, but empirical data indicate that shorter durations (under 90 minutes) minimize physiological stress like in any retained , supporting overall reduction. Long-term empirical evidence links adoption, mandated in U.S. trawls since , to causal reductions in bycatch mortality, as evidenced by declines in strandings correlated with TED enforcement areas. A quantitative assessment of loggerhead strandings in the Southeast U.S. from onward attributed approximately 44% of the observed decrease to TED implementation, based on pre- and post-adoption comparisons controlling for shrimping effort. Similar patterns hold for Kemp's ridley , with TEDs contributing to population recovery alongside nesting protections, though confounding factors such as overall population growth and enhanced stranding reporting complicate attribution. Despite these variables, strandings per unit shrimping effort decreased substantially in TED-required regions compared to non-compliant or pre-mandate baselines.

Impacts on Bycatch and Target Species

Turtle excluder devices (TEDs) have demonstrated substantial reductions in of elasmobranchs beyond sea turtles. In Australia's northern prawn fishery, TEDs reduced catches of large (>1 m) by 86% and large rays (>1 m) by 94%, based on experimental data comparing modified nets to conventional ones. Similarly, in the penaeid shrimp fishery, TEDs decreased bycatch by 94% and shark bycatch by 31%, according to analyses of observer data from 2001–2007. These effects stem from the grid's bar spacing, which allows smaller elasmobranchs to pass through while excluding larger individuals, thereby mitigating risks for . For finfish , TEDs show variable but often positive outcomes, particularly when paired with finfish or deflectors. In southeastern U.S. trials, a side-opening finfish separator integrated with a achieved up to 70% reduction in finfish bycatch during daytime trawling and 50% at night, preserving shrimp catch efficiency. (NMFS) evaluations position TEDs as multi-species bycatch reduction tools, excluding not only turtles but also juvenile finfish and other non-target vertebrates that enter trawl nets, which supports balance by curbing incidental mortality. However, efficacy depends on TED design and trawl conditions; some configurations may retain smaller finfish, limiting total finfish exclusion to scenarios with complementary devices. Regarding target species, TEDs result in minimal shrimp loss, with reanalyses of NMFS paired-trawl experiments from 1988–1990 indicating average reductions of 5–6% in waters for properly installed devices. Inshore applications may experience slightly higher losses (up to 12% initially), but adaptations like accelerator funnels direct through the grid, mitigating escapes and preventing long-term declines in yields. Overall, empirical data from NMFS observer programs confirm no sustained reduction in commercial harvests post-TED implementation, as operational adjustments by fishers offset minor inefficiencies.

Economic and Operational Impacts

Effects on Shrimp Harvest and Fishery Yields

Empirical evaluations of turtle excluder devices (TEDs) have quantified escapement primarily through controlled experiments, revealing losses typically ranging from 0% to 6% depending on design, installation, and fishing grounds. A 2011 reanalysis of historical (NMFS) data for offshore waters in the estimated an average penaeid loss of approximately 6% with common TED configurations like the Georgia TED (5.5-7.5%) and Super Shooter TED (up to 15% with accelerator funnels), attributing prior underestimates to statistical biases in sampling. operational assessments of properly installed TEDs report even lower escapement, between 0% and 2%, emphasizing that losses stem from smaller passing through openings rather than grid deflection. Shrimp loss mechanisms involve hydrodynamic sorting where juveniles escape via the flap or , with higher rates (5-10%) observed in nearshore waters due to smaller average shrimp sizes and , compared to negligible offshore where larger dominate catches. Initial designs caused temporary inefficiencies like clogging from accumulation behind the , potentially increasing sorting labor or reducing tow durations, but adaptations such as accelerator funnels—extended tubes guiding forward—mitigated these by reducing -induced losses by up to 10%. Post-mandate data from the , where requirements took effect in the late 1980s to early 1990s, indicate no sustained decline in overall yields or revenues, with annual landings fluctuating more due to environmental factors like recruitment variability than device-related escapement. NMFS evaluations confirm that while some vessels experienced initial 10% catch reductions, fleet-wide adaptations redistributed effort without net harvest loss, sustaining production near levels of around 85-112 million pounds of tails. Shrimpers' anecdotal claims of 15-20% losses contrast with these findings, which prioritize paired experiments over self-reported data.

Costs, Compliance Burdens, and Fishermen Adaptation

Installation of turtle excluder devices (TEDs) imposes upfront costs on shrimpers typically ranging from $325 to $550 per net, depending on design and materials, with some variations reported as low as $150 to $350 for basic models. Ongoing maintenance requires periodic inspections and repairs to grids and escape openings, compounded by the need for precise rigging to meet regulatory specifications and avoid enforcement penalties such as fines or gear confiscation. Compliance also entails training on installation techniques, often provided through fishery extension programs, to ensure devices function without excessive shrimp loss or structural failure during tows. In the late , these financial and operational burdens fueled widespread resistance among Gulf shrimpers, culminating in protests including harbor blockades and disruptions along the coast in 1989, as fishermen argued that TEDs reduced efficiency and catch viability amid slim profit margins. Initial concerns focused on potential increases in net drag from the grid structure, which could lower tow speeds and raise fuel consumption, though empirical assessments later indicated minimal net impact or even slight improvements in fuel efficiency (1-2% reduction in consumption) by excluding heavier that otherwise burdens the net. Over time, shrimpers adapted through design innovations that mitigated these trade-offs, such as streamlined or soft-grid variants that reduced weight and drag while preserving exclusion efficacy. A notable example is the Georgia Jumper , invented by Georgia shrimper Sinkey Boone in the 1980s and voluntarily adopted by many due to its simple, low-cost construction using lighter materials and top-escape configuration, which aligned regulatory demands with practical fishing needs and fostered broader acceptance via peer-driven diffusion among fishermen. This fisher-led adaptation highlights how targeted modifications can balance compliance costs with operational viability, encouraging sustained use without subsidies in regions where devices proved reliable.

Controversies and Debates

Claims of Ineffectiveness and Failings

Despite their widespread adoption, turtle excluder devices (TEDs) have documented limitations in excluding certain sea turtles, particularly smaller juveniles. Studies have indicated that standard TED escape openings may be insufficient for loggerhead turtles under approximately 50 cm in curved carapace length, leading to entrapment and mortality rates as high as 20-30% in observed interactions for these size classes. This issue arises because the grid bar spacing and escape flap dimensions, typically designed for larger adults, fail to accommodate the slimmer profiles of juveniles, resulting in persistent bycatch even with compliant installations. Improper installation exacerbates these design constraints, with field observations revealing configurations such as excessive grid angles exceeding 55 degrees, inadequate leading edge cuts, or sewn flaps that prevent turtle egress and trap animals inside the net. Bar spacing irregularities or obstructed escape openings further contribute to entrapment, as turtles require immediate access to exit routes to avoid exhaustion and . In challenging conditions like rough seas or extended tows beyond 2 hours, TED performance can degrade due to flap displacement or grid instability, though empirical data on outright structural failures remains limited; behavioral factors, such as ' disorientation or inability to orient toward escapes under fatigue, lead to higher retention rates. Additionally, TEDs inadvertently exclude larger economic species, including finfish and occasionally crabs that exceed grid spacing, as the rigid grids block non-target catchables alongside , per trawl assessments. Critiques highlight over-reliance on TEDs as a singular solution, noting that strandings in trawl-impacted regions continued to rise post-adoption—attributed partly to increased shrimping effort and growing populations—while ignoring broader threats like longline fisheries and habitat degradation. These persistent strandings, documented through necropsy linking drownings to trawl interactions, underscore that TEDs do not eliminate all risks, especially for species or sizes not optimally addressed by current designs.

Regulatory Overreach and Legal Challenges

In January 2024, the Shrimp Association filed a against the (NMFS) under the Biden administration, challenging a rule mandating turtle excluder devices (TEDs) in inshore waters as arbitrary and capricious under the (APA). The plaintiffs argued that NMFS failed to provide evidence of presence or in these shallow, estuarine areas, relying instead on flawed extrapolations from offshore data and outdated mortality models that overestimate risks without site-specific surveys. The U.S. District Court for the Eastern granted to the defendants in June 2025, dismissing the claims with prejudice, though critics contend the ruling overlooked evidentiary gaps in demonstrating causal links between inshore shrimping and mortality. Conversely, environmental groups like the Center for Biological Diversity have pursued litigation to close perceived regulatory loopholes, such as a 2019 Trump-era rule exempting skimmer trawl vessels under 40 feet from requirements in the Gulf and South Atlantic. Filed in April 2021, the suit alleged that these exemptions would result in approximately 1,300 preventable deaths annually, based on estimates from observer data, and violated the Endangered Species Act by inadequately addressing cumulative interactions. Proponents of the exemptions counter that smaller vessels operate in nearshore zones with lower turtle densities and shorter tow times, rendering universal mandates inefficient and unsupported by granular risk assessments that account for seasonal migrations and habitat preferences. Historically, U.S. enforcement of TEDs extended beyond domestic waters through Section 609 of 101-162, which imposed shrimp import embargoes on non-compliant nations starting in , escalating to full bans by the mid-1990s against countries like , , and that did not mandate comparable devices. These measures, justified by estimates of 11,000 to 44,000 annual turtle drownings in global trawls, faced WTO challenges in the United States—Import Prohibition of Certain and Products case (1998), where panels ruled the bans discriminatory for lacking equivalency assessments and phases, though the U.S. prevailed on appeal after revisions. Detractors highlighted disproportionate economic costs—estimated at hundreds of millions in lost exports for developing nations—relative to uncertain attribution of turtle recoveries to TEDs alone, as population trends also reflect nest protection and habitat measures. Debates persist over seasonal waivers and area-specific exemptions, with data indicating bycatch risks vary significantly; for instance, Gulf loggerhead interactions peak in winter offshore but drop near zero in summer inshores, suggesting blanket rules may impose undue burdens without proportional conservation gains. NMFS has occasionally granted temporary waivers during low-risk periods, but critics argue enforcement lacks adaptive, data-driven flexibility, prioritizing uniform compliance over empirical validation of localized threats.

Balanced Assessment of Environmental vs. Economic Trade-offs

The implementation of turtle excluder devices (TEDs) in the late 1980s correlated with substantial rebounds in populations, with nesting females increasing from approximately 702 nests in 1985 to over 18,000 by 2011, a trajectory attributed partly to TEDs' reduction of at-sea drowning mortality estimated at 97% exclusion efficacy in tested designs. Conservation advocates credit TEDs for lowering rates that previously accounted for up to 40% of juvenile and subadult mortality in shrimp trawls, facilitating exponential growth phases observed through the 1990s and early 2000s. However, causal attribution to TEDs alone is diluted by concurrent multi-factor interventions, including U.S.- head-start programs releasing over 100,000 hatchlings since the , intensified nest protection at Rancho Nuevo beaches reducing predation losses by over 90%, and episodic declines in shrimping effort due to market conditions, which collectively enhanced survivorship across life stages. Shrimp industry stakeholders, particularly vessel operators, have long contested mandatory adoption, arguing that initial shrimp yield reductions—perceived as high as 17% in early designs—imposed disproportionate economic burdens during the and , when low ex-vessel prices and costs threatened small-boat viability without commensurate marginal gains in protection relative to baseline risks. Empirical assessments indicate actual long-term losses averaged 0-5% with adapted TEDs, alongside ancillary benefits like reduced finfish improving net efficiency, yet upfront retrofitting expenses (around $400 per device) and operational adaptations fueled resistance, with fishermen advocating voluntary incentives over federal mandates to align with localized economic incentives. Synthesizing available data, TEDs yield a net biodiversity positive by empirically curtailing a key anthropogenic mortality vector, supporting turtle population stabilization and growth amid broader threats like habitat loss, though over-attributing recovery solely to TEDs overlooks synergistic conservation efforts and ignores post-2009 nesting declines linked to environmental factors. Economically, while verifiable hardships—such as extended work hours and marginal profitability squeezes—afflicted shrimpers during rollout, the devices' minimal sustained impact on target catches underscores that trade-offs favor environmental imperatives when quantified causally, yet underscore the need for property rights-oriented policies, like performance-based subsidies, to mitigate livelihood disruptions without compromising efficacy. This realism tempers advocacy narratives, recognizing TEDs' role in causal chains of recovery while acknowledging industry adaptations that have since normalized operations.

Recent Developments and Global Context

Ongoing Innovations and Testing

Recent testing by NOAA Fisheries has confirmed that current turtle excluder device (TED) designs achieve 97 percent efficacy in excluding s from trawls. In 2025, NOAA completed projects evaluating modified TEDs with reduced bar spacing, successfully excluding smaller juvenile turtles while maintaining compatibility with commercial trawling operations in the . These adaptations address limitations in excluding undersized turtles, with field trials demonstrating no significant loss in catch . Innovations incorporate advanced monitoring techniques, including video observations and passive acoustic systems, to verify turtle escapes and detect impacts during trials. Acoustic enumeration projects, funded by NOAA since 2023, use underwater sound recordings to quantify interactions with TED grids, providing empirical data on exclusion performance beyond visual sightings. Video footage from 2024-2025 tests captured wild sea s navigating escape routes, confirming real-world functionality and addressing concerns over undetected entrapments in varied conditions. US-led research emphasizes durable TED variants suitable for international fleets, influencing designs exported to tropical shrimp fisheries. Ongoing collaborations with industry focus on flexible and hard-grid hybrids that withstand prolonged use while excluding additional such as trash and , as tested in multi-species exclusion evaluations. These efforts build on NOAA's global expertise in TED refinement, prioritizing data-driven modifications over unverified assumptions.

International Use and Policy Evolution

In Australia, the Australian Fisheries Management Authority (AFMA) mandated the use of turtle excluder devices (TEDs) in the Northern Prawn Fishery from July 1, 2000, requiring their installation in otter trawls operating in waters north of 19°30'S latitude to mitigate sea turtle bycatch. This policy built on voluntary trials in the 1990s, which demonstrated TED effectiveness in excluding turtles while adapting designs for local species like flatback and olive ridley turtles, with exclusion rates exceeding 90% in controlled tests. Australian adaptations included larger grid sizes for bigger-bodied species such as leatherbacks, reflecting empirical adjustments based on regional bycatch data rather than uniform international standards. The has pursued TED adoption more gradually, with directives encouraging their use in Mediterranean trawl fisheries since the early 2010s, though mandatory enforcement lagged until recent proposals. In 2019, Regulation (EU) 2019/1241 outlined technical specifications for s, including escape openings for , but implementation varied by member state, with trials in and waters showing 80-97% turtle exclusion rates depending on configuration and tow duration. By 2022, advocacy from organizations like highlighted persistent non-compliance in high-bycatch areas, prompting the to plan binding TED specifications for 2026 to align with goals. These policies incorporated variations for loggerhead and green prevalent in EU waters, prioritizing rigid over flexible designs for better performance against larger individuals. In developing nations, TED uptake has faced significant hurdles, including high initial costs—estimated at $500-2,000 per device—and operational complexities in small-scale fleets, leading to compliance rates below 50% in countries like and despite legal requirements. U.S. trade embargoes under 609 of the Act, enforced from 1996 onward, pressured exporters such as , , and to certify TED programs for market access, resulting in WTO disputes (e.g., et al. v. U.S., 1998-2001) where panels upheld the measures but criticized their unilateral application without comparable conditions for sea turtles in non-shrimp fisheries. Local studies in these regions often question universal efficacy, citing lower exclusion rates (around 70-85%) for smaller turtles and minimal shrimp yield impacts, yet embargoes drove adoption over purely economic incentives. Policy evolution internationally has increasingly integrated TEDs with bycatch reduction devices (BRDs) for finfish, as seen in Australian and FAO-guided frameworks since the mid-2000s, where combined systems reduced discards by 30-60% alongside exclusions. This reflects data-driven refinements from global trials, emphasizing modular designs that address multiple taxa without compromising target catches, though enforcement gaps persist in low-resource settings.