A brief comparison of PET analysis methods

Single-bolus studies

**Table 1.** Comparison of analysis methods for single-bolus PET studies
Method	Outcome	Requirements for		Applicable to parametric imaging	Vulnerabilities
Method	Outcome	PET scan	Input	Applicable to parametric imaging	Vulnerabilities
Fit to compartment model (gold standard) or reference tissue input model	Transport and binding/metabolism rate constants, vascular volume, perfusion, V_T, K_i	Dynamic study	arterial plasma	no, except K₁, K_i, or V_T images	None, if comprehensive model. All plasma input methods are vulnerable to systematic errors in plasma metabolite analysis. Possibly nonspecific binding in plasma (f_P)
	BP_ND, R₁	Dynamic study	reference tissue	yes/no (depending on model)	Nonspecific binding in tissue (free fraction f_ND)
	Transport and binding/metabolism rate constants, vascular volume, volumes of distribution (V_T), BP_F, BP_P, BP_ND, R₁	Dynamic study	arterial plasma and reference tissue	yes/no (depending on model)	Possibly nonspecific binding in plasma and/or tissue (f_P and f_ND)
Spectral analysis	K_i or V_T, number of identifiable compartments	Dynamic study	arterial plasma	yes	Nonspecific binding in plasma and/or tissue (f_P and f_ND)
Ratio	BP_ND	Dynamic study	reference tissue	yes	Nonspecific binding in tissue (f_ND), vascular volume, bias dependent on BP
Ratio	Ratio, approaches BP_ND	Single scan	reference tissue	yes	Time from injection, nonspecific binding in tissue (f_ND), vascular volume
Multiple-time graphical analysis (MTGA): Patlak and Logan plots	K_i	Dynamic study	arterial plasma	yes	Errors in plasma metabolite analysis, nonspecific binding to plasma proteins (f_P)
	K_i^ref	Dynamic study	reference tissue	yes	Nonspecific binding in tissue (f_ND)
	V_T	Dynamic study	arterial plasma	yes	Errors in plasma metabolite analysis, nonspecific binding in plasma and tissue (f_P and f_ND)
	DVR (V_T/V_ND)	Dynamic study	reference tissue	yes	Nonspecific binding in tissue (f_ND), reference k₂
Dual time point Patlak plot	K_i	Two late scans	arterial plasma at time of scans	yes	Population average of Patlak y axis intercept
Dual time point Patlak plot	K_i^ref	Two late scans	reference tissue at time of scans	yes	Population average of reference tissue AUC
Fractional uptake rate	FUR, approaches K_i	Single scan	arterial plasma	yes	Errors in plasma metabolite analysis, distribution volumes of free and nonspecifically bound radioligand, vascular volume
Standardized uptake value	SUV	Single scan	i.d.	yes	Perfusion, peripheral clearance, nonspecific binding in plasma and tissue (f_P and f_ND), vascular volume, dose extravasation
Autoradiography (ARG)	Perfusion (f)	Single scan	arterial blood	yes	Partition coefficient (p), vascular volume, time delay

The outcome of many of the methods is the (equilibrium) volume of distribution V_T (or DV). If valid reference region exists, the regional distribution volume ratio can be calculated as DVR = DV_ROI/DV_REFERENCE. This, in turn, relates to the binding potential BP_ND: BP_ND = DVR - 1. However, this measure is vulnerable to change of nonspecific binding in tissue.

Bolus + infusion studies

**Table 2.** Comparison of analysis methods for bolus/infusion PET studies
Method	Outcome	Requirements for		Applicable to parametric imaging	Vulnerabilities
Method	Outcome	PET scan	Input	Applicable to parametric imaging	Vulnerabilities
Ratio	BP_ND	Single scan	reference tissue	yes	nonspecific binding in tissue (f_ND), vascular volume
Ratio	V_T	Single scan	venous plasma	yes	nonspecific binding in tissue (f_ND), vascular volume

Computer-aided diagnosis (CAD)

Computer-aided diagnosis aims to help physicians in the interpretation of medical images, combining physics, mathematics, statistics, medicine, and artificial intelligence. CAD systems are organ- and disease-specific, and the applications are rapidly expanding (Suzuki & Chen, 2018).

Literature

Bertoldo A, Rizzo G, Veronese M. Deriving physiological information from PET images: from SUV to compartmental modelling. Clin Transl Imaging 2014; 2: 239-251. doi: 10.1007/s40336-014-0067-x.

Gjedde A, Wong DF. Mathematical modeling and the quantification of brain dynamics. Neuromethods 2012; 71: 23-39. doi: 10.1007/7657_2012_55.

Innis RB, Cunningham VJ, Delforge J, Fujita M, Gjedde A, Gunn RN, Holden J, Houle S, Huang SC, Ichise M, Iida H, Ito H, Kimura Y, Koeppe RA, Knudsen GM, Knuuti J, Lammertsma AA, Laruelle M, Logan J, Maguire RP, Mintun MA, Morris ED, Parsey R, Price JC, Slifstein M, Sossi V, Suhara T, Votaw JR, Wong DF, Carson RE. Consensus nomenclature for in vivo imaging of reversibly binding radioligands. J Cereb Blood Flow Metab. 2007; 27(9): 1533-1539.

Logan J, Alexoff D, Kriplani A. Simplifications in analyzing positron emission tomography data: effects on outcome measures. Nucl Med Biol. 2007; 34: 743-756.

Slifstein M, Laruelle M. Models and methods for derivation of in vivo neuroreceptor parameters with PET and SPECT reversible radiotracers. Nucl Med Biol. 2001; 28: 595-608.

Suzuki K, Chen Y (eds.): Artificial Intelligence in Decision Support Systems for Diagnosis in Medical Imaging. Springer, 2018. doi: 10.1007/978-3-319-68843-5.

Wong DF, Gründer G, Brasic JR. Brain imaging research: Does the science serve clinical practice? Int Rev Psychiatry 2007; 19(5): 541-558.

Tags: Analysis, Modeling

Updated at: 2018-08-13
Created at: 2008-11-28
Written by: Vesa Oikonen