Aging-Related Changes in Cardiac Sympathetic Function in Humans, Assessed by 6-¹⁸F-Fluorodopamine PET Scanning

MATERIALS AND METHODS

RESULTS

The older and younger groups did not differ significantly in terms of systolic and diastolic blood pressures (127 ± 5/67 ± 3 and 120 ± 9/65 ± 3 mm Hg, respectively), heart rate (65 ± 3 and 62 ± 3 bpm, respectively), or body mass (81 ± 4 and 73 ± 5 kg, respectively).

By 5 min after the 3-min infusion of 6-¹⁸F-fluorodopamine, the mean left ventricular myocardial concentration of 6-¹⁸F-fluorodopamine-derived radioactivity was higher in the older group (9,578 ± 536 Bq · kg/mL · MBq) than in the younger group (7,533 ± 435 Bq · kg/mL · MBq) (P = 0.007) (Fig. 1; Table 1). The mean level of 6-¹⁸F-fluorodopamine-derived radioactivity in arterial whole blood at this time was also higher in the older group than in the younger group (2,306 ± 157 and 1,794 ± 118 Bq · kg/mL · MBq, respectively) (P = 0.013), and myocardial perfusion was also greater (0.976 ± 0.008 and 0.661 ± 0.0065 mL/min/g, respectively) (P = 0.03) (Table 1). The plasma metabolite concentration was higher in the older group than in the younger group (1,890 ± 181 and 1,653 ± 156 Bq · kg/mL · MBq, respectively) (P < 0.001).

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FIGURE 1.

Time-activity curves for myocardial and arterial whole-blood 6-¹⁸F-fluorodopamine-derived radioactivity in older (>50 y old) and younger (<40 y old) healthy volunteers. LV = left ventricular myocardium.

The peak myocardial concentration of 6-¹⁸F-fluorodopamine (attained at about 10 min), divided by the area under the curve for the delivery of arterial blood 6-¹⁸F-fluorodopamine, provided a measure of myocardial extraction of the tracer. Cardiac uptake of 6-¹⁸F-fluorodopamine-derived radioactivity averaged 74% in the younger group and 48% in the older group (P = 0.02).

By 5 min after the 3-min infusion of 6-¹⁸F-fluorodopamine, 6-¹⁸F-fluorodopamine-derived radioactivity levels in the older and younger groups were similar in the liver (6,764 ± 429 and 6,845 ± 497 Bq · kg/mL · MBq, respectively), spleen (6,389 ± 694 and 6,428 ± 834 Bq · kg/mL · MBq, respectively), renal cortex (28,109 ± 2,256 and 28,998 ± 9,148 Bq · kg/mL · MBq, respectively), and renal pelvis (25,126 ± 3,746 and 29,609 ± 9,010 Bq · kg/mL · MBq, respectively). Biliary excretion, reflected by radioactivity in the gallbladder, was substantially greater in the older subjects than in the younger subjects (9,702 ± 206 and 4,591 ± 464 Bq · kg/mL · MBq, respectively) (P = 0.0009). Similarly, after 3 h, the excretion of radioactivity in urine was greater in the older group than in the younger group (23.5 ± 0.9 and 16.3 ± 1.5 ΜΒq, respectively) (P = 0.003), as was the percentage of injected tracer in urine (59% ± 5% and 44% ± 5%, respectively) (P = 0.05).

DISCUSSION

In this study, left ventricular myocardial levels of radioactivity after administration of the sympathoneural imaging agent 6-¹⁸F-fluorodopamine were higher in people more than 50 y old than in people less than 40 y old. At first glance, the higher radioactivity levels in the older group would suggest an increased density of cardiac sympathetic innervation or an increased extraction of the tracer via the cell membrane norepinephrine transporter, because uptake 1 is the main means for removing circulating catecholamines in the human heart (5). After adjustment for the delivery of 6-¹⁸F-fluorodopamine via coronary perfusion, however, the results actually led to the opposite inference, that cardiac uptake 1 activity decreases as people age.

The older group had increased myocardial perfusion, quantified from ¹³NH₃ scanning (18). The finding of increased myocardial perfusion in older subjects, which might seem counterintuitive, actually agrees with previous reports (19–21). One possible explanation for increased myocardial perfusion in the older group would be increased cardiac work at rest (19). Using ¹⁵O-water, Senneff and colleagues did not note a change in myocardial blood flow with increasing subject age (22).

The older group also had higher arterial plasma 6-¹⁸F-fluorodopamine concentrations than did the younger group. The combination of greater left ventricular myocardial blood flow and higher 6-¹⁸F-fluorodopamine concentrations resulted in a substantially increased calculated delivery of 6-¹⁸F-fluorodopamine to the heart. When myocardial extraction of the tracer was quantified from the peak left ventricular myocardial level of 6-¹⁸F-fluorodopamine-derived radioactivity divided by the area under the curve for the arterial blood 6-¹⁸F-fluorodopamine concentration over time, the cardiac uptake of 6-¹⁸F-fluorodopamine averaged 74% in the younger group but only 48% in the older group.

Because the cardiac extraction of ³H-norepinephrine normally averages about 70%–80% in young adult subjects (5,23), the cardiac extraction of 6-¹⁸F-fluorodopamine seems about the same as that of norepinephrine (13).

Even during the 3-min infusion of 6-¹⁸F-fluorodopamine, myocardial 6-¹⁸F-fluorodopamine-derived radioactivity in the older group exceeded that in the younger group. During the initial 5 min, myocardial radioactivity appears to reflect both neuronal uptake of 6-¹⁸F-fluorodopamine and extraneuronal cellular uptake of O-methylated metabolites of 6-¹⁸F-fluorodopamine (17), which form very rapidly (24). Increased extraneuronal formation of metabolites of 6-¹⁸F-fluorodopamine could explain this early differentiation between the groups. Consistent with this explanation, by 5 min after the injection of 6-¹⁸F-fluorodopamine, the total concentration of metabolites in plasma was higher in the older group; in addition, the older group had significantly higher levels of 6-¹⁸F-fluorodopamine-derived radioactivity in the gallbladder and urine, a result that would be expected if there were more extraneuronal O-methylation and conjugation of the tracer.

Decreased cardiac uptake 1 activity might reflect decreased density of innervation or decreased numbers or function of transporter sites. The present results could not distinguish these possibilities. Because the rates of cardiac production of dihydroxyphenylglycol and dihydroxyphenylalanine, which are indices of the turnover and synthesis of norepinephrine in myocardial sympathetic nerves (25,26), do not change with aging (1), the density of innervation appears to remain unchanged. Right atrial tissue obtained during open-heart surgery from elderly patients without apparent heart failure shows a decreased accumulation of ³H-norepinephrine and a decreased shift of the norepinephrine concentration-response curve by desipramine, compared with tissue from pediatric patients with acyanotic congenital heart disease (27). These findings favor the notion of decreased numbers or function of cell membrane norepinephrine transporter sites on intact sympathetic nerves as a determinant of decreased cardiac uptake 1 activity with aging.

Assaying myocardial tissue norepinephrine concentrations might seem a straightforward way to distinguish the loss of sympathetic nerves from decreased activity of the membrane norepinephrine transporter; however, low norepinephrine concentrations might not necessarily indicate sympathetic denervation in this setting, because conditions in which norepinephrine turnover exceeds synthetic capacity also produce myocardial norepinephrine depletion (28). It has been reported that in cardiac conduction paths from tissue freshly obtained at autopsy, the contents of tyrosine hydroxylase and dopamine-β-hydroxylase decrease with aging (29); this finding does indicate denervation. Aged rats also have evidence of decreased tyrosine hydroxylase activity, on the basis of the responses of tissue norepinephrine contents to treatment with α-methyl-p-tyrosine, an inhibitor of tyrosine hydroxylase (30). As noted above, however, cardiac production of endogenous l-dihydroxyphenylalanine does not appear to change with normal human aging.

Goldstein et al. recently developed a kinetic model for the fate of 6-¹⁸F-fluorodopamine in the human heart (17). When a greater input of 6-¹⁸F-fluorodopamine was applied to the model, the predicted time-activity curve for myocardial 6-¹⁸F-fluorodopamine-derived radioactivity was clearly displaced upward from the empiric curve. That is, the actual amount of myocardial 6-¹⁸F-fluorodopamine-derived radioactivity was smaller than predicted, assuming that there were no changes in cardiac sympathetic function in the older group. When assigned values for effective rate constants in the model were varied for uptake 1, a 32% decrease in the value for the effective rate constant for uptake 1 yielded excellent curve fit, in agreement with the finding of decreased peak myocardial 6-¹⁸F-fluorodopamine-derived radioactivity for a given amount of delivery by coronary perfusion.

A few PET ligands have been used for sympathetic neuroimaging in the heart in clinical research. ¹¹C-Hydroxyephedrine and 6-¹⁸F-fluorometaraminol (31–34) are not substrates for the catecholamine-metabolizing enzymes monoamine oxidase and catechol-O-methyltransferase and therefore have a metabolic fate in sympathetic nerves different from that of endogenous norepinephrine. In contrast, 6-¹⁸F-fluorodopamine has a disposition similar to that of endogenous catecholamines. l-¹¹C-Norepinephrine has not been used because of difficulty in synthesizing the stereoisomer.

An aging-related decline in uptake 1 activity would be expected to enhance the delivery of catecholamines to adrenoceptors in the heart for a given amount of neuronally released or circulating catecholamine. This scenario in turn might help explain the well-known aging-related downregulation of β-adrenoceptor-mediated processes.

CONCLUSION

Left ventricular myocardial levels of radioactivity after the administration of 6-¹⁸F-fluorodopamine are higher in people more than 50 y old than in people less than 40 y old; however, after adjustment for the delivery of 6-¹⁸F-fluorodopamine via coronary perfusion, the evidence indicates decreased cardiac uptake 1 activity as people age.