References
- Chen K, Bandy D, Reiman E, Huang SC, Lawson M, Feng D, Yun LS, Palant A. 1998. Noninvasive quantification of the cerebral metabolic rate for glucose using positron emission tomography, 18F-fluoro-2-deoxyglucose, the Patlak method, and an image-derived input function. J Cerebr Blood Flow Metab. 18:716–723.
- Dakua SP. 2013. Use of chaos concept in medical image segmentation. Comput Methods Biomech Biomed Engin. 1(1):28–36.
- Fregonara ZP, Fadaili M, Maroy R, Comtat C, Souloumiac A, Jan S, Ribeiro MJ, Gaura V, Hen BA, Trbossen R. 2009. Comparison of eight methods for the estimation of the image-derived input function in dynamic [18F]-FDG PET human brain studies. J Cerebr Blood Flow Metab. 29:1825–1835.
- Harrison TM, Weintraub S, Mesulam MM, Rogalski E. 2012. Superior memory and higher cortical volumes in unusually successful cognitive aging. J Int Neuropsych Soc. 18(6):1081–1085.
- Hauser EB. 2013. Laplace transform in tracer kinetic modeling, Paper presented at INAC2013. Proceedings of International Nuclear Atlantic Conference; 1–7; Recife, Brazil.
- Hauser EB, Venturin GT, Greggio S, Costa JC. 2015. Mathematical modeling to quantify the pharmacokinetic process of [18F]2-fluor-2deoxy-D-glucose (FDG). In: Constanda C, Kirsch A, editors. Integral methods in science and engineering. Cham (Birkhäuser); p. 301–308.
- Hauser EB, Venturin GT, Greggio S, Manica E, Zimmer ER, Costa JC. 2017. Laplace transform method for 11C-PIB two-tissue reversible compartment model with image-derived arterial input function. Ibero-Latin American Congress on Computational Methods in Engineering. Florianópolis (Brazil); 1–10.
- Hays MT, Watson EE, Thomas SR, Stabin M. 2002. MIRD dose estimate report No. 19: radiation absorbed dose estimates from 18F-FDG. J Nucl Med. 43:210–214.
- Khalil M. 2011. Basic sciences of nuclear medicine. Berlin (Heidelberg): Springer.
- Kuhn FP, Warnock G, Burger C, Ledermann K, Kilbour MR, Martin-Soelch C, Buck. 2014. Comparison of PET template-based and MRI-based image processing in the quantitative analysis of C11-raclopride PET. EJNMMI Res. 4:1–7.
- Laforest R, Sharp TL, Engelbach JA, Fetting NM, Herrero P, Kim J, Lewis JS, Rowland DJ, Tai YC, Welch MJ. 2005. Measurement of input functions in rodents: challenges and solutions. Nucl Med Biol. 3:679–685.
- Lopresti BJ, Klunk WE, Mathis CA, Hoge JA, Ziolko SA, Lu X, Meltzer CC, Schimmel K, Tsopelas D, DeKosky ST, et al. 2005. Simplified quantification of Pittsburgh compound B amyloid imaging PET studies: a comparative analysis. J Nucl Med. 46(12):1959–1972.
- Marquardt DW. 1963. An algorithm for least-squares estimation of nonlinear parameters. J S Industr Appl Math. 11:431–441.
- Pagani M, De Carli F, Morbelli S, Buschiazzo, Sambuceti G, Berg J, Chincarini A, Frisoni GB, Galluzzi S, Perneczky R, et al. 2015. Volume of interest-based [18F]fluorodeoxyglucose PET discriminates MCI converting to Alzheimer’s disease from healthy controls. Eur Alzheimer’s Dis Consortium Study. 7:34–42.
- Reitan RM. 1979. Manual for administration of neuropsychological test batteries for adults and children. Tucson (AZ): Neuropsychology Laboratory.
- Shaikh F, Savells D, Awan O, Inayat I, Chaudhry, Jerath, Graham MM. 2015. Quantitative imaging analysis of FDG PET/CT imaging for detection of central neurolymphomatosis in a case of recurrent diffuse B-cell lymphoma. Cureus. 7(11):1–8.
- Su Y, Blazey TM, Snyde AZ, Raichle ME, Hornbeck RC, Aldea P, Morris JC, Benzinger TLS. 2015. Quantitative amiloid imaging using image-derived arterial input function. PLoS One. 10(4):1–16.
- Zaidi H. 2006. Quantitative analysis in nuclear medicine imaging. Newyork (NY): Springer.
- Zhou S, Chen K, Reiman EM, Li D, Shanet B. 2012. A method for generating image-derived input function in quantitative 18F-FDG PET study based on the monotonicity of the input and output function curve. Nucl Med Commun. 33(4):362–370.