Introduction

Arrhythmogenic right ventricular cardiomyopathy/dysplasia (ARVC/D) is a disease that predominantly affects the right ventricle (RV), although biventricular involvement may occur in advanced disease [1]. ARVC/D is characterized by structural derangements that may cause a broad range of signs and symptoms. Yet, disease expression is highly variable and incomplete in most patients, confounding both the diagnostic process and clinical management, particularly during early disease stages [2].

The histopathological hallmark of ARVC/D is fibrofatty replacement of the RV myocardium. Apoptosis has been proposed as an important mechanism that mediates the slow, ongoing loss of heart muscle cells which is followed by ventricular dysfunction [3]. How fibrofatty replacement and apoptosis are related in ARVC/D is a matter of speculation. The possibility to detect apoptosis in vivo in ARVC/D may lead to a better understanding of the pathophysiological mechanism underlying disease progression [4]. In vivo imaging of cardiac apoptosis with the use of 99mTc-annexin V has been proven feasible, as 99mTc-annexin V binds to exposed phosphatidylserine (PS) on the outer surface of apoptotic cells [5]. Accordingly, 99mTc-annexin V has been effectively used to noninvasively visualize regions of apoptosis in patients with various pathologies [69], as well as in experimental models [10, 11]. We aimed to establish whether cardiac apoptosis can be assessed noninvasively in patients with ARVC/D.

Methods

Patients

The institutional review board approved the study protocol and informed consent was obtained from all study subjects. Six ARVC/D patients were examined. The patients, who fulfilled the ARVC/D Task Force criteria [12], were randomly taken from the cohort of ARVC/D patients at our institution. Patients were evaluated when they were in a clinically stable condition (no ventricular tachyarrhythmias or heart failure symptoms during the 2 months prior to inclusion). In all patients, molecular genetic analysis was performed and focused on known mutations related to ARVC/D; these included plakophilin-2 (PKP2), desmoplakin (DSP), desmoglein-2 (DSG2), desmocollin-2 (DSC2), plakoglobin (JUP), and transmembrane protein 43 (TMEM43) [13, 14]. No patient had a history of coronary artery disease, diabetes or hypertension.

Scintigraphy

Patients were intravenously injected with 600 MBq of 99mTc HYNIC-rh-annexin V (99mTc-annexin V), and 4 h after administration, single photon emission computed tomography (SPECT) scans were acquired using a dual-headed gamma camera equipped with a 3/8” NaI(Tl) crystal and combined with a low-dose CT scanner (Infinia; General Electric Medical Systems, Haifa, Israel). SPECT scans were acquired with low-energy, high-resolution collimators, a 15% energy window on the 140 keV photopeak, according to a step-and-shoot protocol with a total of 90 frames and 30 s per frame in a 128×128 matrix and a zoom of 1.28. SPECT images were iteratively reconstructed (OSEM) and corrected for attenuation using the low-dose CT scans from the Infinia scanner (no intravenous contrast material).

Analysis of scintigraphic data

To define the anatomical borders of the myocardium within the thorax, anatomical tomographic images are essential and the low-dose CT images of the Infinia could not be used for this purpose. Therefore, tomographic anatomical images from contrast-enhanced CT or cardiac MR imaging performed prior to implantable cardioverter defibrillator (ICD) implantation and within 2 months of 99mTc-annexin V scintigraphy were reviewed for all subjects. To align the anatomical images with the SPECT data, first the matrix size of the anatomical images was adjusted to the matrix size of the SPECT data (128×128) and second the images were automatically aligned (MultiModality; HERMES Medical Solutions, Sweden). To semiquantify 99mTc-annexin V myocardial uptake, three regions of interest (ROI) including the RV wall, interventricular septum (IVS) and left ventricle (LV) free wall were drawn on three summed mid-myocardial horizontal long axis anatomical images. To correct for background activity (i.e. nonspecific uptake), a separate region was drawn on both lungs. As there were no differences between the two lung regions, these values were aggregated to one value (mean counts per pixel). The ROIs were determined on the anatomical images and were subsequently copied to the aligned SPECT images. 99mTc-annexin V uptake in each separate ROI was calculated as the ratio of the mean counts per pixel in the specific myocardial region to the mean counts per pixel in the total myocardium (i.e. the sum of all three ROIs). Both the regional and the total myocardial activity were corrected for background activity by subtraction of nonspecific uptake. The attenuation-corrected SPECT data were used for analysis. The reader was blinded to the clinical information.

Follow-up

Long-term follow-up data were obtained from at least one of three sources: visit to the outpatient clinic; review of the patient’s hospital records; personal communication with the patient’s physician. This analysis focused on the occurrence of ventricular arrhythmias, appropriate ICD discharge, and sudden cardiac death. One patient was lost to follow-up. The mean follow-up was 27 ± 8 months (range 18–57 months).

Statistical analysis

Data are presented as means ± SD. Mean values were compared for differences using the (un)paired Student’s t-test when appropriate. For multiple comparisons, means were compared for differences using analysis of variance (ANOVA) with a post-hoc Bonferroni correction (SPSS for Windows 16.0.2.1; SPSS, Chicago, IL). A p value <0.05 was considered to indicate statistical significance.

Results

Clinical spectrum

Table 1 summarizes the demographic/clinical data. All patients fulfilled the ARVC/D Task Force criteria [12]. Their mean age at clinical presentation was 36.7 ± 13.9 years (range 19–55 years) and 33% (two) were women. In five patients, ventricular tachycardia (VT) with left bundle branch block morphology was the first expression of ARVC/D. One patient presented with syncope. Two patients had a positive family history of premature sudden cardiac death. All patients had normal LV function by echocardiography and all patients had an ICD. All patients had a history of haemodynamically unstable VT. Four patients were on antiarrhythmic agents. One patient had the C796R mutation in PKP2, while one had the T335A mutation in DSG2. In the remaining patients, no DNA mutations were found. One patient (patient 6) had severe segmental dilatation of the RV on echocardiography (major ARVC/D Task Force criterion [12]). The other five patients had regional RV hypokinesia (patients 2, 3 and 5), mild segmental dilatation of the RV (patient 4) and mild global RV dilatation with normal LV function (patient 1) on echocardiography (minor ARVC/D Task Force criteria [12]).

Table 1 Clinical characteristics of patients with ARVC/D

Myocardial 99mTc-annexin V uptake

Figure 1 shows a typical example of a patient who exhibited increased 99mTc-annexin V uptake in the RV wall (patient 2). Overall, the RV wall showed a higher 99mTc-annexin V uptake (1.328 ± 0.437) than the LV wall (0.936 ± 0.175, p = 0.049) or the IVS (0.902 ± 0.222, p = 0.026). There was no difference in 99mTc-annexin V uptake between the LV wall and the IVS (p = 0.986). However, the overall higher uptake of 99mTc-annexin V in the RV wall could be explained by the fact that 50% of patients (patients 3, 5 and 6) showed increased 99mTc-annexin V uptake in the RV compared to the other three patients (patients 1, 2 and 4; 1.788 ± 0.133 vs 0.983 ± 0.034 respectively, p = 0.001; Fig. 2).

Fig. 1
figure 1

Coregistered transaxial images of patient 3 (left cardiac MR image, right 99mTc-annexin SPECT scintigraphy image). There is increased 99mTc-annexin V uptake in the RV wall (IVS interventricular septum, LV left ventricular free wall)

Fig. 2
figure 2

99mTc-annexin uptake in the RV wall, IVS and LV wall calculated as the ratio of the uptake (mean counts per pixel) in the vvparticular myocardial region to the uptake in the total myocardium (i.e. the sum of all three ROIs)

Within 2 months of 99mTc-annexin V scintigraphy, cardiac MR images were available in three patients (patients 2, 3 and 4). Only patient 3 showed increased uptake of 99mTc-annexin V. The increased uptake of 99mTc-annexin V was located in the lateral wall of the RV, while the MR images showed an overall dilated RV with regional dyskinesia of the apex. It is therefore not possible to draw any conclusions as to a potential correlation between cardiac MRI RV abnormalities and the location of increased uptake of 99mTc-annexin V.

Follow-up

The extent of 99mTc-annexin V uptake in the RV wall did not distinguish patients with arrhythmias within 2 years after 99mTc-annexin V scintigraphy from those without, nor did it distinguish patients in whom a gene mutation was found from those in whom it was not (Table 2).

Table 2 Follow-up in ARVC/D patients on the occurrence of ventricular arrhythmias, appropriate ICD discharge and sudden cardiac death

Discussion

Apoptosis is a significant pathophysiological feature of ARVC/D and is a consistent post-mortem finding in both the RV and LV [1, 15]. In this study, 99mTc-annexin V scintigraphy was performed with the purpose of establishing whether apoptosis can be visualized in vivo in patients with ARVC/D. Our results demonstrated increased 99mTc-annexin V uptake in the RV free wall of three ARVC/D patients, suggestive of RV-specific apoptotic activity in these patients. The variation in myocardial uptake of 99mTc-annexin V between patients is not surprising and might partly be explained by the random distribution and the episodic nature of the apoptotic process [16]. Furthermore, patients differed with respect to the time since diagnosis and severity of morphological abnormalities. These variations were probably reflected by differences in myocardial uptake of 99mTc-annexin V.

All our ARVC/D patients had a history of documented VT episodes. Mallat et al. speculated that apoptosis in ARVC/D might result from repetitive ventricular tachyarrhythmia episodes [15]. Furthermore, apoptotic myocytes are frequently found in regions of the myocardium which are not subjected to invasion by adipocytes and fibrosis, suggesting that the loss of myocytes through apoptosis occurs as a primary process before adipocytes and fibrous tissues fill the vacant cellular space. Also, Valente et al. have reported that apoptosis is present in endomyocardial biopsy samples of patients with ARVC/D, especially in the early symptomatic phase of the disease [17].

The exposure of PS on the cell surface is a general marker of apoptotic cells. Externalization of nonapoptotic PS is induced by several activation stimuli, including engagement of immunoreceptors. Externalized PS is observed in apoptotic, injured, infected, senescent and necrotic cells, and becomes a target for recognition by phagocytes [1820]. Thus, in addition to acting as a marker of apoptosis, annexin V may be a marker of inflammation and cell stress. Accordingly, the myocardial uptake of 99mTc-annexin V is most likely not only a marker of apoptosis, but may also partly reflect local inflammation. Patchy inflammatory infiltrates in RV are consistently reported in ARVC/D, both in in vitro and in in vivo examinations [3, 21, 22].

Patchy cell death combined with inflammatory infiltration is a common histological finding in ARVC/D [23]. The inflammation might be a reaction to proinflammatory cytokines induced by cell death and/or apoptosis or caused by an infectious myocarditis (e.g. viral infection) [21, 24]. Although it is most likely that these factors are, at least to some extent, interrelated, it is not known whether there is a causal relationship between inflammation and cell death in ARVC/D. However, it remains unclear whether myocarditis in ARVC/D is disease-initiating (a primary event) or a reaction to processes initiated by ARVC/D.

Study limitations and clinical usefulness

The first limitation of our study is the small number of patients. The observation of 99mTc-annexin V myocardial uptake in three out of six patients might be explained by the random distribution and the episodic nature of the apoptotic process. Second, no cardiac biopsies were obtained. Therefore, a validation of the 99mTc-annexin V myocardial uptake with histology was not possible.

Recently modification of the highly specific ARVC/D Task Force criteria (published in 1994) has been proposed [25]. The revision incorporates new knowledge and technology to improve especially the sensitivity of the Task Force criteria without changing the high specificity. However, at the time of patient inclusion the 1994 criteria were used [12]. As expected, because of the relatively unchanged specificity, reevaluation of the patients included in our study according to the new criteria did not change the clinical diagnosis in any patient.

Conclusion

Apoptosis may be detected noninvasively in ARVC/D, and this may lead to a better understanding of the role of apoptosis in the pathophysiology of ARVC/D. Whether it will allow monitoring of the disease course or the response to various treatments aimed at counteracting disease progression remains to be studied.