What does this research mean for the field?

Larger individuals of the blood cockle Anadara granosa in Indonesia accumulate significantly higher concentrations of microplastics, predominantly polyethylene, posing an extreme dietary hazard to human consumers. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This study investigates how body size and habitat influence microplastic accumulation in A. granosa.

May 19, 2026Open Access

Microplastic bioaccumulation in blood cockles (Anadara granosa) from Indonesia: Influence of body size, habitat, and human dietary risk assessment

Key Points

This study investigates how body size and habitat influence microplastic accumulation in A. granosa.
Collected 150 Anadara granosa specimens from five different locations in Indonesia.
Identified microplastics using stereo microscopy and Fourier Transform Infrared Spectroscopy (FT-IR).
Conducted statistical analyses (ANOVA, correlation, PCA) to assess microplastic accumulation.
Larger A. granosa specimens had nearly double the microplastic concentration compared to smaller ones.
Polyethylene was the dominant polymer, comprising 57.82% of the total microplastic found.
Estimated annual human intake of microplastic particles from A. granosa varies between 6240 and 46,800 particles per individual.

Abstract

Microplastics (MPs) contamination has emerged as a significant environmental threat that may disrupt the ecological functions of coastal systems. Despite this, there is a distinct lack of comprehensive research regarding microplastic bioaccumulation in A. granosa within Indonesia, one of the world's largest contributors to marine plastic pollution. Addressing this knowledge gap is vital for assessing the potential dietary risks these bivalves pose to human health. This study aims to investigate variations of MPs in A. granosa influenced by body size and habitat together with assessing ecological risks and potential human dietary exposure. A total of 150 specimens were collected from five locations, with MPs characteristic shape, color, and size identified via stereo microscopy and polymer types determined using Fourier Transform Infrared Spectroscopy (FT-IR). Statistical analyses (ANOVA, correlation, and PCA) revealed that MPs accumulation was significantly influenced by both locations and organism size ( p < 0.05). Notably, large specimens exhibited nearly double the MPs concentration of smaller individuals, specifically regarding fibers, fragments, and particles in the <100 μm and 200–1000 μm classes. Location WA (West Aceh), the industrial zone, recorded the highest contamination levels. PCA established a strong correlation between fragments, gray coloration, and particles <100 μm, while Polyethylene (PE) was identified as the predominant polymer (57.82%). Risk assessments utilizing the Pollution Load Index (PLI) and Polymer Hazard Index (PHI) categorized the organisms as Level II (High) and Level V (Most Hazardous), respectively. Furthermore, annual human dietary intake from consuming A. granosa was estimated to range from 6240 to 46,800 MPs particles/individual/year across various age groups. These findings provide critical baseline data for assessing the ecotoxicological impacts of MPs and highlight the urgent need for effective marine conservation and public health strategies in Indonesia. • Larger individuals of Anadara granosa exhibited higher microplastic ingestion. • Polyethylene (PE) was the dominant polymer type, accounting for 57.82% of total microplastic abundance. • Estimated annual human dietary intake from A. granosa consumption ranged from 6240 to 46,800 microplastic particles per individual. • All of specimens were classified as Level V (Extreme Danger) based on Polymer Hazard Index (PHI) assessment.

Microplastic bioaccumulation in blood cockles (Anadara granosa) from Indonesia: Influence of body size, habitat, and human dietary risk assessment

Key Points

Abstract

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