[1] [1] F. Parenti, G. Beretta, M. Berti, V. Arioli, “Teichomycins, new antibiotics from Actinoplanes teichomyceticus, Nov. Sp. I. Description of the producer strain, fermentation studies and biological properties," J. Antibiot. 31, 276–283 (1978).

[2] [2] A. Borghi, P. Antonini, M. Zanol, P. Ferrari, L. F. Zerilli, G. C. Lancini, “Isolation and structure de-termination of two new analogs of teicoplanin, a glycopeptide antibiotic," J. Antibiot. 42, 361–366 (1989).

[3] [3] M. J. Wood, “The comparative efficacy and safety of teicoplanin and vancomycin," J. Antimicrob. Che-mother. 37, 209–222 (1996).

[4] [4] J. D. Knudsen, K. Fuursted, F. Espersen, N. Fri-modt-Moller, “Activities of vancomycin and teico-planin against penicillin-resistant pneumococci in vitro and in vivo and correlation to pharmacokinetic parameters in the mouse peritonitis model," Anti-microb. Agents Ch. 41, 1910–1915 (1997).

[5] [5] H. Li, X. Wang, H. Y. Dong, Y. L. Dong, G. Tian, “Clinical analysis of therapeutic drug monitoring and drug dosage for ICU patients treated with teicoplanin," Chin. J. Clin. Pharmacol. Therapeut. 16, 538–544 (2011).

[6] [6] N. Mochizuki, K. Ohno, T. Shimamura, H. Fur-ukawa, S. Todo, S. Kishino, “Quantitative deter-mination of individual teicoplanin components in human plasma and cerebrospinal fluid by high-per-formance liquid chromatography with electrochem-ical detection," J. Chromatogr. B 847, 78–81 (2007).

[7] [7] H. J. Chang, P. C. Hsu, C. C. Yang, L. K. Siu, A. J. Kuo, J. H. Chia, T. L. Wu, C. T. Huang, M. H. Lee, “Influence of teicoplanin MICs on treatment out-comes among patients with teicoplanin-treated methicillin-resistant Staphylococcus aureus bacter-aemia: A hospital-based retrospective study," J. Antimicrob. Chemother. 67, 736–741 (2012).

[8] [8] F. H. Y. Fung, J. C. Y. Tang, J. P. P. Hopkins, J. J. Dutton, L. M. Bailey, A. S. Davison, “Measurement of teicoplanin by liquid chromatography-tandem mass spectrometry: Development of a novel meth-od," Ann. Clin. Biochem. 49, 475–481 (2012).

[9] [9] R. Welle, W. Greten, B. Rietmann, S. Alley, G. Sin-naeve, P. Dardenne, “Near-Infrared Spectroscopy on chopper to measure maize forage quality parameters online," Crop. Sci. 43, 1407–1413 (2003).

[10] [10] H. Z. Chen, T. Pan, J. M. Chen, Q. P. Lu, “Waveband selection for NIR spectroscopy analysis of soil organic matter based on SG smoothing and MWPLS methods," Chemometr. Intell. Lab. 107, 139–146 (2011).

[11] [11] J. M. Chen, T. Pan, G. S. Liu, Y. Hun, D. X. Chen, “Selection of stable equivalent wavebands for near-infrared spectroscopic analysis of total nitrogen in soil," J. Innov. Opt. Health Sci. 7, 1350071–1– 1350071–9 (2013).

[12] [12] T. Pan, M. M. Li, J. M. Chen, “Selection method of quasi-continuous wavelength combination with applications to the near-infrared spectroscopic analysis of soil organic matter," Appl. Spectrosc. 68, 263–271 (2014).

[13] [13] H. S. Guo, J. M. Chen, T. Pan, J. H. Wang, G. Cao, “Vis-NIR wavelength selection for non-destructive discriminant analysis of breed screening of trans-genic sugarcane," Anal. Methods 6, 8810–8816 (2014).

[14] [14] J. Y. Chen, C. Iyo, F. Terada, S. Kawano, “Effect of multiplicative scatter correction on wavelength se-lection for near-infrared calibration to determine fat content in raw milk," J. Near Infrared Spectrosc. 10, 301–307 (2002).

[15] [15] Z. Y. Liu, B. Liu, T. Pan, J. D. Yang, “Determination of amino acid nitrogen in tuber mustard using near-infrared spectroscopy with waveband selection stability," Spectrochim. Acta A 102, 269–274 (2013).

[16] [16] A. C. Sousa, M. M. L. M. Lucio, O. F. Bezerra Neto, G. P. S. Marcone, A. F. C. Pereira, E. O. Dantas, W. D. Fragoso, M. C. U. Araujo, R. K. H. Galvao, “A method for determination of COD in a domestic wastewater treatment plant by using near-infrared reflectance spectrometry of seston," Anal. Chim. Acta 588, 231–236 (2007).

[17] [17] T. Pan, Z. H. Chen, J. M. Chen, Z. Y. Liu, Near-infrared spectroscopy with waveband selection sta-bility for the determination of COD in sugar refinery wastewater," Anal. Methods 4, 1046–1052 (2012).

[18] [18] T. Pan, J. M. Liu, J. M. Chen, G. P. Zhang, Y. Zhao, “Rapid determination of preliminary thalas-saemia screening indicators based on near-infrared spectroscopy with wavelength selection stability," Anal. Methods 5, 4355–4362 (2013).

[19] [19] T. Pan, M. M. Li, J. M. Chen, H. Y. Xue, “Quantification of glycated henoglobin indicator HbA1c through near-infrared spectroscopy," J. Innov. Opt. Health Sci. 7, 1350060 (2014).

[20] [20] J. G. Rosas, H. D Waard, T. D. Beer, C. Vervaet, J. P. Remon, W. L. J. Hinrichs, H. W. Frijlink, M. Blanco, “NIR spectroscopy for the in-line monitor-ing of a multicomponent formulation during the entire freeze-drying process," J. Pharm. Biomed. Anal. 97, 39–46 (2014).

[21] [21] T. Pan, A. Hashimoto, M. Kanou, K. Nakanishi, T. Kameoka, “Development of a quantification system of ionic dissociative metabolites using an FT-IR/ATR method," Bioprocess Biosyst. Eng. 26, 133–139 (2003).

[22] [22] T. Pan, A. Hashimoto, M. Kanou, K. Nakanishi, T. Kameoka, “Mid-infrared spectroscopic quantification of ionic dissociative metabolites based on three spectral extraction methods," Jpn. J. Food Eng. 5, 22–31 (2004).

[23] [23] X. L. Long, G. S. Liu, T. Pan, J. M. Chen, “Waveband selection of reagent-free determination for thalassemia screening indicators using Fourier transform infrared spectroscopy with attenuated total reflection," J. Biomed. Opt. 19, 087004 (2014).

[24] [24] K. Zou, Q. Zhang, Y. Xia, “Culture medium opti-mization for teicoplanin production by response surface analysis," Chin. J. Antibiot. 36, 671–675 (2011).

[25] [25] S. R. Cheong, S. Y. Kim, Y. W. Lee, J. K. Lee, H. K. Jung, B. S. Koo, Microorganism and the process for the production of teicoplanin: US, 7432080B2[P]. 2008–10–07.

[26] [26] W. Z. Lu, Modern Near-Infrared Spectroscopy An-alytical Technology (China petrochemical press, Beijing, 2007).