[2] NAJI A, KHAN F R, HASHEM S H. Potential human health risk assessment of trace metals via the consumption of marine fish in Persian Gulf[J]. Marine Pollution Bulletin, 2016, 109(1): 667-671.
[3] ADEL M, OLIVERI C G, DADAR M, et al. Heavy metal concentrations in edible muscle of whitecheek shark, Carcharhinus dussumieri (elasmobranchii, chondrichthyes) from the Persian Gulf: A food safety issue[J]. Food & Chemical Toxicology, 2016, 97: 135-140.
[4] ARDUINI F, PALLESCHI G. Screening and confirmatory methods for the detection of heavy metals in foods persistent organic[C]. Pollutants and Toxic Metals in Foods, Woodhead Publishing Series in Food Science Technology and Nutrition, Cambridge, 2013.
[5] CUI Lin, WU Jie, JU Huang-xian. Electrochemical sensing of heavy metal ions with inorganic, organic and bio-materials[J]. Biosensors & Bioelectronics, 2015, 63(63): 276-286.
[6] MOHAMMAD B, TAPEH N, MAHYARI M, et al. Monitoring of trace amounts of heavy metals in different food and water samples by flame atomic absorption spectrophotometer after preconcentration by amine-functionalized graphene nanosheet[J]. Environmental Monitoring and Assessment, 2014, 186(11): 7245-7257.
[7] CHEN X, YUAN L, CHEN X, et al. A strategy for rapid identification of healthy Tegillarca granosa from among those contaminated with unspecified heavy metals using infrared spectroscopy [J]. Analytical Methods, 2017, 9(30): 4447-4454.
[8] CHEN X, LIU K, CAI J, et al. Identification of heavy metal-contaminated Tegillarca granosa using infrared spectroscopy [J]. Analytical Methods, 2015, 7(5): 2172-81.
[9] CHEN X, WU D, GUAN X, et al. Feasibility of infrared and Raman spectroscopies for identification of juvenile black seabream (sparus macrocephalus) intoxicated by heavy metals[J]. Journal of Agricultural and Food Chemistry, 2013, 61(50): 12429-12435.
[10] SHI T, CHEN Y, LIU Y, et al. Visible and near-infrared reflectance spectroscopy-an alternative for monitoring soil contamination by heavy metals[J]. Journal of Hazardous Materials, 2014, 265(2): 166-176.
[12] OLUMEGBON I A, OLOYEDE A, AFARA I O. Near-infrared (NIR) spectroscopic evaluation of articular cartilage: a review of current and future trends[J]. Applied Spectroscopy Reviews, 2016, 52(6): 1-19.
[13] GALBACS G. A critical review of recent progress in analytical laser-induced breakdown spectroscopy [J]. Analytical and Bioanalytical Chemistry, 2015, 407(25): 7537-7562.
[16] YUAN L-M, CHEN X, LAI Y, et al. A novel strategy of clustering informative variables for quantitative analysis of potential toxics element in tegillarca granosa using laser-induced breakdown spectroscopy[J]. Food Analytical Methods, 2018, 11(5): 1405-1416.
[17] LIU K, CHEN X, LI L, et al. A consensus successive projections algorithm-multiple linear regression method for analyzing near infrared spectra [J]. Analytica Chimica Acta, 2015, 858: 16-23.
[18] JI G, HUANG G, YANG Z, et al. Using consensus interval partial least square in near infrared spectra analysis [J]. Chemometrics and Intelligent Laboratory Systems, 2015, 144: 56-62.
[19] GARCIMUO M, PACE D M D, BERTUCCELLI G. Laser-induced breakdown spectroscopy for quantitative analysis of copper in algae[J]. Optics & Laser Technology, 2013, 47(4): 26-30.
[20] CHEN X, DING H, YUAN L M, et al. New approach of simultaneous, multi‐perspective imaging for quantitative assessment of the compactness of grape bunches[J/OL]. Australian Journal of Grape and Wine Research, 2018, doi: 10.1111/ajgw.12349.
[21] NI W, BROWN S D, MAN R. Stacked partial least squares regression analysis for spectral calibration and prediction[J]. Journal of Chemometrics, 2009, 23(10): 505-517.
