Analysis of [ 11 C]L-deprenyl-D2 (DEP-D) brain PET studies

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Turku PET Centre Modelling report TPCMOD0033 2006-05-26 Vesa Oikonen Analysis of [ 11 C]L-deprenyl-D2 (DEP-D) brain PET studies Introduction L-deprenyl and monoamine oxidase B Monoamine oxidase B (MAO B) is present in the outer mitochondrial membrane occurring in the brain predominantly in glial cells and in serotonergic neurons [Fowler et al., 2005]. It oxidizes amines (for example dopamine) from both endogenous and exogenous sources. MAO B is selectively and irreversibly inhibited by L-deprenyl (selegiline). When the enzyme-substrate complex is formed, the rate-limiting step of MAO B catalyzed oxidation creates a highly reactive intermediate, which forms a covalent bond with the enzyme, thus irreversibly inactivating it [Fowler et al., 2005]. When L-deprenyl is labelled with 11 C, the active enzyme MAO B becomes labelled, and it can be imaged in vivo with PET. Three-compartment model A three-compartment model can be applied to the time-activity curves (TACs) of labelled L- deprenyl in the brain and plasma to estimate MAO B activity in the brain. In the model, K 1 represents the plasma-to-organ transfer constant, k 2 is the transfer rate of radiotracer from organ back to plasma, and k 3 describes the rate of binding to MAO B. Under the PET study conditions, k 3 is proportional to the functionally active free enzyme concentration. Because binding is irreversible, it is assumed that k 4 =0. From these model constants, K 1 and k 2 are dependent on blood flow, but k 3 is not. Due to the high extraction of L-deprenyl, K1 is dominated by blood flow instead of capillary permeability [Fowler et al., 1988, 1995]. Also the net influx rate K i (=K 1 *k 3 /(k 2 +k 3 )) is dependent on blood flow [Lammertsma et al., 1991], as well as the more directly radiotracer uptake related parameters, like SUV. The very high rate of binding of labelled L-deprenyl to MAO B creates difficulties in applying the model. The estimates of k 2 and k 3 tend to be highly correlated, and the rate of radiotracer binding (k 3 ) and delivery (K 1 ) are hard to separate [Fowler et al., 2005]. Especially in the brain regions of high MAO B concentrations (basal ganglia, thalamus and cingulate gyrus), and in the elderly people who have reduced blood flow, the rate limiting step is the radiotracer delivery instead of binding [Fowler et al., 1993]. To reduce the problem with correlating k 2 and k 3, a combination model parameter k 3 has been introduced as an index of MAO B activity; is the K 1 over k 2 ratio [Fowler et al., 1993 and 1995]. K 1 and k 2 are both dependent on the blood flow, but and k 3 are independent of blood flow. Because this index contains the ratio k 3 /k 2, the effect of their (positive) correlation is expected to be smaller. Reproducibility in test/retest studies was improved by using k 3 instead of k 3 [Logan et al., 2000]. Deuterium substitution The rate-limiting step of MAO B catalyzed oxidation involves cleavage of a certain carbonhydrogen bond in L-deprenyl. A carbon-deuterium bond is more difficult to cleave than the carbon-

hydrogen bond, which leads to reduced rate of reaction when this hydrogen is substituted with deuterium (so called deuterium isotope effect). Because the very high binding rate of [ 11 C]Ldeprenyl has been found to be problematic in quantification of MAO B activity, the deuteriumsubstituted L-deprenyl, [ 11 C]L-deprenyl-D2 is therefore preferred as PET radiotracer [Fowler et al., 1988, 1995, 2004]. Confounding factors Age Unlike most enzymes, MAO B activity ( k 3 ) increases clearly with normal aging, which is accompanied by decreasing blood flow (K 1 ) [Fowler et al., 1997]. Therefore, the age must be controlled in the PET studies of MAO B. If the age effect is studied, the measured index of MAO B activity must not be flow dependent. The age-related and disease-associated increase of MAO B has been attributed to neuron loss and gliosis (increase in glial cells). Blood flow As described above, the tissue uptake of [ 11 C]L-deprenyl-D2 and especially [ 11 C]L-deprenyl is strongly dependent on blood flow. Therefore, to quantification of MAO B activity, the compartment model and a blood flow independent model parameter or index, like k 3 or k 3 must be used. Otherwise, for example, the increase of MAO B activity in epileptogenic region might be underestimated because of subsequently reduced blood flow. Smoking MAO B is highly and variably inhibited in smokers [Fowler et al., 2003]. An overnight abstinence for smokers does not produce any recovery of MAO B activity. However, smoking a single cigarette does not produce a measurable decrease in MAO B activity in non-smokers [Fowler et al., 2003]. Decreased K 1 in later scans In the test-retest setting, Logan et al. (2000) noticed a decrease of K 1 in the second scan (-7.7 ± 13.2%), although the decrease was not statistically significant (n=5). This may be caused by familiarization with the PET procedure and decreased anxiety [Logan et al., 2000]. Corrections for the PET data The brain concentrations of [ 11 C]L-deprenyl-D2 peak at about 5 min after injection, and after a washout phase the concentrations reach a plateau about 30 min after injection [Fowler et al., 1995]. Blood volume correction Fowler et al. (1995) subtracted from the PET data an approximate 4% blood volume before analyzing the data using the three-compartment model or graphical analysis for irreversible systems.

Lammertsma et al. (1991) included the vascular volume fraction in the model equations, noting that whole blood curve must be used instead of (total) plasma curve. Plasma protein binding Free fraction in plasma was 6.0% [Fowler et al., 2004]. Considering the high K 1 estimates, dissociation rate of the radiotracer from plasma protein may be high, so that most of protein bound radiotracer is also available for transport to the tissue. Blood-to-plasma transformation For [ 11 C]L-deprenyl, Lammertsma et al. measured the blood-to-plasma ratio from discrete samples between 5 and 90 min. Based on in vitro experiments, they assumed that the plasma-to-blood ratio is 1.126 at the time of the arrival of the tracer in the blood, taken to be the time where the blood curve increased above 1% of the peak value [Lammertsma et al., 1991]. They fitted a multiexponential function to the ratios, determining the number of exponentials based on AIC and SC. The multi-exponential function was then used to calculate the total plasma curve from arterial blood curve which had been measured on-line. Fowler and Logan et al. do not give details on this transformation in their publications. Plasma metabolite correction For [ 11 C]L-deprenyl, Lammertsma et al. measured the fraction of plasma metabolites from four samples at 5, 10, 15 and 20 min, and fitted a single exponential function to the fractions, assuming no metabolites at time 0. The exponential function was used to calculate the concentration of unchanged tracer in the plasma. Fowler and Logan et al. do not give details on this correction in their publications. Time delay correction Lammertsma et al. (1991) corrected for the time delay between blood curve and whole brain PET data by including the delay as one of the fitted model parameters. The smaller ROIs were then fitted with the delay fixed to this value. Graphical analysis Fowler et al. (1995) have used graphical analysis for irreversible systems to calculate the net influx rate K i. Ki were taken as an average of slopes between 6 and 45 min and 6 and 55 min [Fowler et al., 1995]. Estimation of K 1 and k 3 using linear method Nonlinear method Fowler et al. (1988, 1995) and Logan et al. (2000) estimated the three-compartment model parameters using traditional nonlinear least squares approach.

Linear method Fowler et al. (1997, 1999) and Logan et al. (2000) estimated the three-compartment model parameters K 1 and k 3 in a procedure which involves also graphical analysis: 1) K i is calculated using the average of graphical analysis slopes between 6-45 min and 7-55 min 2) K 1 (and k 2 +k 3 ) are estimated with bilinear regression using a modification of the method of Blomqvist (Eq. 1); note that equations in the original articles from years 1997 and 1998 do not contain the necessary square brackets. Logan et al. (2000) describe this process in more detail: Several values for K 1 were estimated by successively increasing the maximum time T from 5 to 18 min, because K 1 is more sensitive to data at earlier time points; an average K 1 was used in the next step. 3) k 3 is calculated by solving it from the equation that relates K i to the three-compartment model parameters (Eq. 2). ( ) = T T t 1 () + ( 2 + ) 3 (') ' () 0 T ROI T K C p t dt k k K i Cp t dt dt ROI t dt 0 0 0 K1Ki λk3 = ( 2) K1 Ki The estimates of K 1 and k 3 from this linear method correlated very well with the estimates from the nonlinear method [Logan et al., 2000]. No noise-induced bias was noticed in the linear method, and the repeatability was also similar. K 1 and blood flow Extraction of [ 11 C]L-deprenyl-D2 is high, and assuming that it is 1, then K 1 would equal plasma flow, that is about 40% of blood flow. Therefore, the K 1 estimates by Logan et al. (2000), ranging from 0.476 to 0.845, are quite high. The step 2) may lead to an overestimation of K 1, if the blood volume in tissue is not considered: blood volume correction was not mentioned by Fowler et al. (1997, 1999) or Logan et al. (2000). Graphical method without plasma sampling Graphical method (Gjedde-Patlak plot) can be used to estimate the net MAO B uptake using either metabolite corrected plasma or reference tissue with no MAO B as model input. To compensate the significant amount of MAO B in cerebellum, the cerebellar time-activity curves can be multiplied by a mono-exponential function to correct the deviation from linearity [Bergström et al., 1998]. However, cerebellar MAO B activity is probably not constant between individuals, although in clinical studies this methods has been used [Kumlien et al., 2001], and even less so in MAO B inhibition studies. Note that the results of graphical method are not independent from blood flow, although the flow effects may be smaller than with SUV. () 1 References

Bergström M, Kumlien E, Lilja A, Tyrefors N, Westerberg G, Lånström B. Temporal lobe epilepsy visualized with PET with 11 C-L-deuterium-deprenyl - analysis of kinetic data. Acta Neurol. Scand. 1998; 98: 224-231. Fowler JS, Logan J, Volkow ND, Wang G-J. Translational neuroimaging: positron emission tomography studies of monoamine oxidase. Mol. Imaging Biol. 2005; 7: 377-387. Fowler JS, Logan J, Wang G-J, Volkow ND. Monoamine oxidase and cigarette smoking. Neurotoxicol. 2003; 24: 75-82. Fowler JS, Logan J, Wang G-J, Volkow ND, Telang F, Ding Y-S, Shea C, Garza V, Xu Y, Li Z, Alexoff D, Vaska P, Ferrieri R, Schlyer D, Zhu W, Gatley SJ. Comparison of the binding of the irreversible monoamine oxidase tracers, [ 11 C]clorgyline and [ 11 C]l-deprenyl in brain and peripheral organs in humans. Nucl. Med. Biol. 2004; 31: 313-319. Fowler JS, Volkow ND, Cilento R, Wang G-J, Felder C, Logan J. Comparison of brain glucose metabolism and monoamine oxidase B (MAO B) in traumatic brain injury. Clin. Pos. Imag. 1999; 2:71-79. Fowler JS, Volkow ND, Logan J, Schlyer DJ, MacGregor RR, Wang G-J, Wolf AP, Pappas N, Alexoff D, Shea C, Gatley SJ, Dorflinger E, Yoo K, Morawsky L, Fazzini E. Monoamine oxidase B (MAO B) inhibitor therapy in Parkinson's disease: the degree and reversibility of human brain MAO B inhibition by Ro 19 6327. Neurology 1993; 43: 1984-1992. Fowler JS, Volkow ND, Wang GJ, Logan J, Pappas N, Shea C, MacGregor R. Age-related increases in brain monoamine oxidase B in living healthy human subjects. Neurobiol Aging 1997; 18: 431-435. Fowler JS, Wang G-J, Logan J, Xie S, Volkow ND, MacGregor RR, Schlyer DJ, Pappas N, Alexoff DL, Patlak C, Wolf AP. Selective Reduction of Radiotracer Trapping by Deuterium Substitution: Comparison of Carbon-11-L-Deprenyl and Carbon-11-Deprenyl-D2 for MAO B Mapping. J. Nucl. Med. 1995; 36: 1255-1262. Fowler JS, Wolf AP, MacGregor RR, Dewey SL, Logan J, Schlyer DJ, Langstrom B. Mechanistic positron emission tomography studies: demonstration of a deuterium isotope effect in the monoamine oxidase-catalyzed binding of [ 11 C]L-deprenyl in living baboon brain. J. Neurochem. 1988; 51: 1524-1534. Kumlien E, Nilsson A, Hagberg G, Långström B, Bergström M. PET with 11 C-deuterium-deprenyl and 18 F-FDG in focal epilepsy. Acta Neurol. Scand 2001; 103: 360-366. Lammertsma AA, Bench CJ, Price GW, Cremer JE, Luthra SK, Turton D, Wood ND, Frackowiak RSJ. Measurement of Cerebral Monoamine Oxidase B Activity Using L-[ 11 C]Deprenyl and Dynamic Positron Emission Tomography. J. Cereb. Blood Flow Metab. 1991; 11: 545-556. Logan J, Fowler JS, Volkow ND, Wang G-J, MacGregor RR, Shea C. Reproducibility of repeated measures of deuterium substituted [ 11 C]L-deprenyl ([ 11 C]L-deprenyl-D2) binding in the human brain. Nucl. Med. Biol. 2000; 27:43-49.

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