<p>Aflatoxin B1 (AFB<sub>1</sub>) contamination and micronutrient deficiencies pose a major challenge to food safety and nutritional security. This study elucidated the synergistic potential of boron (B) and zinc (Zn) co-application to fortify nutritional quality and mitigate AFB<sub>1</sub> accumulation in turnip (<i>Brassica rapa</i> L) roots. Seeds were cultivated in soils amended with individual or combined B and Zn at concentrations of 10–25&#xa0;mg kg<sup>− 1</sup>. In results, individual B supplementation at 20&#xa0;mg kg<sup>− 1</sup> optimized protein content (10.9%), and the B-Zn interactome provided superior overall metabolic performance. B-Zn synergy significantly enhanced physiological resilience. Specifically, the combined application at 15–20&#xa0;mg kg<sup>− 1</sup> consistently achieved the highest STI and GMP productivity across biochemical traits. Carbohydrate partitioning was significantly improved, with NFE reaching 74.1% at 20&#xa0;mg kg<sup>− 1</sup> of B + Zn. AFB<sub>1</sub> toxicity was suppressed by 60.08% at 15&#xa0;mg kg<sup>− 1</sup>. RPI of dry matter, protein, and phenolic were consistently positive at 15–20&#xa0;mg kg<sup>− 1</sup> of B + Zn. Co-application enhanced the YSI for NFE, protein, and ash content. PCA confirmed that the synergistic effects of B + Zn treatment provided superior nutritional results compared to individual micronutrient applications. These findings demonstrate that balanced B-Zn supplementation strengthens nutritional composition quality and suppresses AFB<sub>1</sub> contamination, supporting the biofortification paradigm as a reproducible strategy for sustainable food quality and crop improvement.</p>

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Synergistically micronutrient co-application improves nutritional quality and effectively reduces aflatoxin contamination in Brassica rapa L. roots

  • Unays Siraj,
  • Zainab Siraj,
  • Patricio R. De los Ríos-Escalante

摘要

Aflatoxin B1 (AFB1) contamination and micronutrient deficiencies pose a major challenge to food safety and nutritional security. This study elucidated the synergistic potential of boron (B) and zinc (Zn) co-application to fortify nutritional quality and mitigate AFB1 accumulation in turnip (Brassica rapa L) roots. Seeds were cultivated in soils amended with individual or combined B and Zn at concentrations of 10–25 mg kg− 1. In results, individual B supplementation at 20 mg kg− 1 optimized protein content (10.9%), and the B-Zn interactome provided superior overall metabolic performance. B-Zn synergy significantly enhanced physiological resilience. Specifically, the combined application at 15–20 mg kg− 1 consistently achieved the highest STI and GMP productivity across biochemical traits. Carbohydrate partitioning was significantly improved, with NFE reaching 74.1% at 20 mg kg− 1 of B + Zn. AFB1 toxicity was suppressed by 60.08% at 15 mg kg− 1. RPI of dry matter, protein, and phenolic were consistently positive at 15–20 mg kg− 1 of B + Zn. Co-application enhanced the YSI for NFE, protein, and ash content. PCA confirmed that the synergistic effects of B + Zn treatment provided superior nutritional results compared to individual micronutrient applications. These findings demonstrate that balanced B-Zn supplementation strengthens nutritional composition quality and suppresses AFB1 contamination, supporting the biofortification paradigm as a reproducible strategy for sustainable food quality and crop improvement.