<p>The third biggest concentration of metallic ions is traces of the element copper (Cu<sup>2+</sup>), which is crucial to all living creatures and plays a key role in several operations. However, deficiency or excessive copper ions may trigger a wide range of disorders, as determined by cellular requirements. To identify these factors, optical SPR-based refractive index sensors have emerged that&#xa0;concentrate&#xa0;on the swift identification of Cu2 + ions in the present moment,&#xa0;that has excellent selectivity and sensitivity. Here, this paper intends to design and discuss a Four-Quadrant Circular Grid Refractive Index Biosensor (FQCGRIB) with a machine learning approach for detecting heavy metals like Cu<sup>2+</sup>. The four-quadrant circular grid refractive index biosensor enhances conventional biosensor performance via improved accuracy, sensitivity, specificity, and detection efficiency. significant sensitivity values of 719.85&#xa0;nm/RIU, 763.35&#xa0;nm/RIU, 761.90&#xa0;nm/RIU, and 734.52&#xa0;nm/RIU are achieved for n2cu<sup>2+</sup>, n3cu<sup>2+</sup>, n4cu<sup>2+</sup>, and n5cu<sup>2+</sup>, respectively. Simultaneously, a greater detection range of 1175.46, 1175.14, 1176.47, 1189.56, and 1180.59, along with a greater quality factor of 835.35&#xa0;nm/RIU, 828.85&#xa0;nm/RIU, 827.72&#xa0;nm/RIU, 843.21&#xa0;nm/RIU, and 828.57&#xa0;nm/RIU, for the n1cu<sup>2+</sup>, n2cu<sup>2+</sup>, n3cu<sup>2+</sup>, n4cu<sup>2+</sup>, and n5cu<sup>2+</sup>, respectively, is obtained. In addition, the minimal achieved detection limit is 0.000932 for n4cu<sup>2+</sup>, and a greater figure of merit is 382.86 for n4cu<sup>2+</sup>. The high predicted value of 0.981494 has been achieved by the machine learning approach for Cu<sup>2+</sup> ions, and the mean square error value of 0.001987 for Cu<sup>2+</sup> ions. Along with the results, this sensor has a greater capability with compactness in detecting heavy metal ions.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Design and optimization of highly sensitive and tunable nanostructure biosensor for heavy metal detection using machine learning

  • Yogesh Sharma,
  • Trupti Kamani,
  • Zaid Ahmed Shamsan,
  • Shobhit K. Patel

摘要

The third biggest concentration of metallic ions is traces of the element copper (Cu2+), which is crucial to all living creatures and plays a key role in several operations. However, deficiency or excessive copper ions may trigger a wide range of disorders, as determined by cellular requirements. To identify these factors, optical SPR-based refractive index sensors have emerged that concentrate on the swift identification of Cu2 + ions in the present moment, that has excellent selectivity and sensitivity. Here, this paper intends to design and discuss a Four-Quadrant Circular Grid Refractive Index Biosensor (FQCGRIB) with a machine learning approach for detecting heavy metals like Cu2+. The four-quadrant circular grid refractive index biosensor enhances conventional biosensor performance via improved accuracy, sensitivity, specificity, and detection efficiency. significant sensitivity values of 719.85 nm/RIU, 763.35 nm/RIU, 761.90 nm/RIU, and 734.52 nm/RIU are achieved for n2cu2+, n3cu2+, n4cu2+, and n5cu2+, respectively. Simultaneously, a greater detection range of 1175.46, 1175.14, 1176.47, 1189.56, and 1180.59, along with a greater quality factor of 835.35 nm/RIU, 828.85 nm/RIU, 827.72 nm/RIU, 843.21 nm/RIU, and 828.57 nm/RIU, for the n1cu2+, n2cu2+, n3cu2+, n4cu2+, and n5cu2+, respectively, is obtained. In addition, the minimal achieved detection limit is 0.000932 for n4cu2+, and a greater figure of merit is 382.86 for n4cu2+. The high predicted value of 0.981494 has been achieved by the machine learning approach for Cu2+ ions, and the mean square error value of 0.001987 for Cu2+ ions. Along with the results, this sensor has a greater capability with compactness in detecting heavy metal ions.