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Half-life determination of inorganic-organic hybrid nanomaterials in mice using laser-induced breakdown spectroscopy

Yanwu Chu, Zhanjie Zhang, Qianyuan He, Feng Chen, Ziqian Sheng, Deng Zhang, Honglin Jin, Fagang Jiang, Lianbo Guo

2020Journal of Advanced Research37 citationsDOIOpen Access PDF

Abstract

Inorganic or inorganic-organic hybrid nanomaterials have great potential for applications in the biomedical fields. Biological half-life is an essential pharmacokinetic parameter for these materials to function in vivo. Compared to inductively coupled plasma mass spectrometry (ICP-MS), which is the gold standard, laser-induced breakdown spectroscopy (LIBS) is a faster and more efficient elemental detection method. We investigated an efficient way to quantify the metabolic rate using LIBS. Nanoparticle platforms, such as manganese dioxide-bovine serum albumin (MnO2-BSA) or boehmite-bovine serum albumin (AlO(OH)-BSA) were injected into mice through intravenous administration for LIBS spectrum acquisition. First, the spectral background was corrected using the polynomial fitting method; The spectral interference was eliminated by Lorentz fitting for each LIBS spectrum simultaneously. The support vector regression (SVR) was then used for LIBS quantitative analyses. Finally, the LIBS results were compared with the ICP-MS ones. The half-lives of MnO2-BSA calculated by LIBS and ICP-MS were 2.49 and 2.42 h, respectively. For AlO(OH)-BSA, the half-lives detected by LIBS and ICP-MS were 3.46 and 3.57 h, respectively. The relative error of LIBS is within 5% compared to ICP-MS. The results demonstrate that LIBS is a valuable tool for quantifying the metabolic rates with a high degree of accuracy.

Topics & Concepts

Laser-induced breakdown spectroscopyNanomaterialsSpectroscopyMaterials scienceInductively coupled plasma atomic emission spectroscopyAnalytical Chemistry (journal)NanoparticleInductively coupled plasmaMass spectrometryChemistryPlasmaNanotechnologyChromatographyQuantum mechanicsPhysicsLaser-induced spectroscopy and plasmaMercury impact and mitigation studiesMass Spectrometry Techniques and Applications