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Autori principali: Martin, Estella, Wells, Randall S, Berens McCabe, Elizabeth J, Dziobak, Miranda K, Case, Savannah M, Curtin, Tita, Conger, Eric, Gaur, Ayushi, Knowles, Millie A, Allen, Robyn Faulkner, Toms, Christina N, Weinstein, John E, Hart, Leslie B
Natura: Artículo científico
Lingua:en
Pubblicazione: Marine Mammal Science 2026
Accesso online:https://pubmed.ncbi.nlm.nih.gov/42291130/
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author Martin, Estella
Wells, Randall S
Berens McCabe, Elizabeth J
Dziobak, Miranda K
Case, Savannah M
Curtin, Tita
Conger, Eric
Gaur, Ayushi
Knowles, Millie A
Allen, Robyn Faulkner
Toms, Christina N
Weinstein, John E
Hart, Leslie B
author_facet Martin, Estella
Wells, Randall S
Berens McCabe, Elizabeth J
Dziobak, Miranda K
Case, Savannah M
Curtin, Tita
Conger, Eric
Gaur, Ayushi
Knowles, Millie A
Allen, Robyn Faulkner
Toms, Christina N
Weinstein, John E
Hart, Leslie B
Martin, Estella
Wells, Randall S
Berens McCabe, Elizabeth J
Dziobak, Miranda K
Case, Savannah M
Curtin, Tita
Conger, Eric
Gaur, Ayushi
Knowles, Millie A
Allen, Robyn Faulkner
Toms, Christina N
Weinstein, John E
Hart, Leslie B
collection PubMed - marine biology
contents Microplastic Munchies: Exploring Microplastic Trophic Transfer Potential Between Two Key Prey Fish Species and Resident Common Bottlenose Dolphins () in Sarasota Bay, Florida. Martin, Estella Wells, Randall S Berens McCabe, Elizabeth J Dziobak, Miranda K Case, Savannah M Curtin, Tita Conger, Eric Gaur, Ayushi Knowles, Millie A Allen, Robyn Faulkner Toms, Christina N Weinstein, John E Hart, Leslie B Microplastics have been identified in hundreds of species, with evidence of trophic transfer via contaminated prey. Sarasota Bay common bottlenose dolphins () serve as sentinels of coastal pollution, including plastics and chemical plasticizers. Previous research confirmed microplastic ingestion in these dolphins (100.0%, = 7) and extensive contamination in 11 common prey species (96.5%, = 86). This study compared microplastic characteristics in dolphins, Gulf toadfish (, = 30) and pinfish (, = 35), to assess potential trophic transfer. Dolphin ingestion was evaluated using gastric ( = 23) and fecal ( = 15) samples from catch-and-release health assessments (2022-2024), while prey gastrointestinal and muscle tissues were screened. Particles were prevalent across samples (dolphins: 82.6%, pinfish: 97.1%, toadfish: 96.7%), with fibers as the dominant shape. Raman spectroscopy confirmed plastic polymers (PL, PP, and PET) in all species. Pinfish had a higher median particle load (1.4 particles/g tissue) than toadfish (0.6 particles/g tissue; = 0.006). Based on estimated daily food intake (5.96-6.45 kg) and diet composition (toadfish-34.1%, pinfish-38.1%), Sarasota dolphins may ingest more than 10,000 particles/day from these fish alone. Contaminated prey may be vectors for dolphin microplastic exposure. This study emphasizes the need for further research on microplastic pathways in marine food webs and implications for wildlife.
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language en
publishDate 2026
publisher Marine Mammal Science
record_format pubmed
spellingShingle Microplastic Munchies: Exploring Microplastic Trophic Transfer Potential Between Two Key Prey Fish Species and Resident Common Bottlenose Dolphins () in Sarasota Bay, Florida.
Martin, Estella
Wells, Randall S
Berens McCabe, Elizabeth J
Dziobak, Miranda K
Case, Savannah M
Curtin, Tita
Conger, Eric
Gaur, Ayushi
Knowles, Millie A
Allen, Robyn Faulkner
Toms, Christina N
Weinstein, John E
Hart, Leslie B
Microplastic Munchies: Exploring Microplastic Trophic Transfer Potential Between Two Key Prey Fish Species and Resident Common Bottlenose Dolphins () in Sarasota Bay, Florida. Martin, Estella Wells, Randall S Berens McCabe, Elizabeth J Dziobak, Miranda K Case, Savannah M Curtin, Tita Conger, Eric Gaur, Ayushi Knowles, Millie A Allen, Robyn Faulkner Toms, Christina N Weinstein, John E Hart, Leslie B Microplastics have been identified in hundreds of species, with evidence of trophic transfer via contaminated prey. Sarasota Bay common bottlenose dolphins () serve as sentinels of coastal pollution, including plastics and chemical plasticizers. Previous research confirmed microplastic ingestion in these dolphins (100.0%, = 7) and extensive contamination in 11 common prey species (96.5%, = 86). This study compared microplastic characteristics in dolphins, Gulf toadfish (, = 30) and pinfish (, = 35), to assess potential trophic transfer. Dolphin ingestion was evaluated using gastric ( = 23) and fecal ( = 15) samples from catch-and-release health assessments (2022-2024), while prey gastrointestinal and muscle tissues were screened. Particles were prevalent across samples (dolphins: 82.6%, pinfish: 97.1%, toadfish: 96.7%), with fibers as the dominant shape. Raman spectroscopy confirmed plastic polymers (PL, PP, and PET) in all species. Pinfish had a higher median particle load (1.4 particles/g tissue) than toadfish (0.6 particles/g tissue; = 0.006). Based on estimated daily food intake (5.96-6.45 kg) and diet composition (toadfish-34.1%, pinfish-38.1%), Sarasota dolphins may ingest more than 10,000 particles/day from these fish alone. Contaminated prey may be vectors for dolphin microplastic exposure. This study emphasizes the need for further research on microplastic pathways in marine food webs and implications for wildlife.
title Microplastic Munchies: Exploring Microplastic Trophic Transfer Potential Between Two Key Prey Fish Species and Resident Common Bottlenose Dolphins () in Sarasota Bay, Florida.
url https://pubmed.ncbi.nlm.nih.gov/42291130/