What question did this study set out to answer?

This research aims to investigate how Fe-impregnated biochar improves cadmium detoxification and its subcellular compartmentalization in rice plants.

May 10, 2026

Fe‐impregnated biochar enhances cadmium detoxification and compartmentalization in rice

Key Points

This research aims to investigate how Fe-impregnated biochar improves cadmium detoxification and its subcellular compartmentalization in rice plants.
Used iron-impregnated biochar (I-PBC) and water-washed biochar in rice cultivation
Analyzed cadmium levels in the cytosolic fraction and HCl-extractable fractions
Assessed impact on grain cadmium accumulation and compartmentalization mechanisms.
I-PBC significantly increased HCl-extractable cadmium, indicating enhanced conversion to low-toxicity Cd-oxalate complexes
There was increased compartmentalization of cadmium in cytosolic fractions, reducing its soluble forms
I-PBC inhibited grain cadmium accumulation effectively compared to other forms of biochar.

Abstract

, water-washed PBC) suggest that I-PBC enhances Cd compartmentalization in aboveground tissues by increasing Cd in the cytosolic fraction while reducing soluble Cd proportions, likely sequestering Cd into less metabolically active compartments (e.g., vesicles). Additionally, I-PBC promoted the conversion of Cd into low-toxicity Cd-oxalate complexes, as evidenced by a significant increase in the HCl-extractable Cd fraction (FHCl, predominantly Cd-oxalate) in stems. These findings demonstrate that impregnation is superior to co-pyrolysis for Fe-modified biochar in inhibiting grain Cd accumulation, with key mechanisms involving enhanced Cd chelation by oxalic acid and subcellular compartmentalization. This study highlights the potential of low-dose I-PBC for practical Cd-contaminated farmland remediation.

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Fe‐impregnated biochar enhances cadmium detoxification and compartmentalization in rice

Key Points

Abstract

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