Clinical impact of Positron Emission Tomography by coincidence system with 18F-FDG on therapeutic decision-making of patients with ischemic cardiomyopathy after myocardial infarction

Felix, Renata Christian Martins; Correa, Patrícia Lavatori; Azevedo, Jader Cunha de; Dohmann, Hans Fernando da Rocha; Mesquita, Evandro Tinoco; Mesquita, Cláudio Tinoco

doi:10.1590/S0066-782X2006000500003

Abstracts

OBJECTIVE: To evaluate the influence of the myocardium viability study by coincidence imaging using 18F-FDG in the clinical decision-making of patients with ischemic cardiomyopathy and left ventricular dysfunction. METHODS: Thirty-one patients were submitted to myocardial viability study with 18F-FDG by coincidence imaging between September 2003 and November 2004. The physician answered a questionnaire about the choice of therapeutic procedure before and after PET. RESULTS: Twenty-seven patients (87%) had myocardial viability. Twenty-one (68%) physicians thought that PET changed the therapeutic procedure for their patients and 27(87%) considered that PET added to the therapeutic decision. The current treatment decision (clinical or revascularization) correlated with myocardial viability (p=0.006). CONCLUSIONS: Coincidence imaging is a useful tool to help physicians in a difficult decision about the best treatment for patients with ischemic cardiomyopathy. Symptoms, electrocardiogram, ejection fraction and myocardial fibrosis area did not correlate with myocardium viability, so they should not be used to decide whether to perform a myocardial viability study or not.

Ischemic cardiomyopathy; myocardial viability; PET; coincidence system

OBJETIVO: Avaliar a influência da PET por Sistema de Coincidência, na tomada de decisão terapêutica, em pacientes com cardiopatia isquêmica e disfunção ventricular. MÉTODOS: Trinta e um pacientes realizaram PET com FDG-18F por Sistema de Coincidência entre setembro de 2003 e novembro de 2004. Os médicos assistentes responderam a um questionário sobre a proposta terapêutica do paciente antes da PET e após seu resultado. RESULTADOS: Vinte e sete (87%) pacientes apresentaram viabilidade miocárdica. Vinte e um (68%) médicos concordaram em que a PET modificou a terapêutica proposta para o paciente e 27 (87%) acharam que a PET contribuiu diretamente para a conduta tomada, mesmo quando não modificada. O tratamento atual proposto para o paciente (clínico ou revascularização) correlacionou-se com o achado de viabilidade (p=0,006). CONCLUSÕES: A PET pelo Sistema de Coincidência demonstra ser útil por auxiliar o médico na tomada de decisão quanto ao melhor tratamento de pacientes com cardiopatia isquêmica. A sintomatologia, o eletrocardiograma, a fração de ejeção e a área de fibrose miocárdica não se correlacionam com a viabilidade e, portanto, não servem como guia para indicação ou não da realização da PET.

Cardiopatia isquêmica; viabilidade miocárdica; PET; sistema de coincidência

ORIGINAL ARTICLE

Clinical impact of positron emission tomography by coincidence system with ¹⁸F-FDG on therapeutic decision-making of patients with ischemic cardiomyopathy after myocardial infarction

Renata Christian Martins Felix; Patrícia Lavatori Correa; Jader Cunha de Azevedo; Hans Fernando da Rocha Dohmann; Evandro Tinoco Mesquita; Cláudio Tinoco Mesquita

Serviço de Medicina Nuclear do Hospital Pró-Cardíaco, PROCED - Hospital Pró-Cardíaco e Universidade Federal Fluminense - Rio de Janeiro, RJ - Brazil

^{Mailing Address} Mailing Address: Renata Christian Martins Felix Rua General Polidoro, 192 Botafogo 22280-000 - Rio de Janeiro, RJ - Brazil E-mail: renatafelix@cardiol.br ou medicina.nuclear@procardiaco.com.br

ABSTRACT

OBJECTIVE: To evaluate the influence of the myocardium viability study by coincidence imaging using ¹⁸F-FDG in the clinical decision-making of patients with ischemic cardiomyopathy and left ventricular dysfunction.

METHODS: Thirty-one patients were submitted to myocardial viability study with ¹⁸F-FDG by coincidence imaging between September 2003 and November 2004. The physician answered a questionnaire about the choice of therapeutic procedure before and after PET.

RESULTS: Twenty-seven patients (87%) had myocardial viability. Twenty-one (68%) physicians thought that PET changed the therapeutic procedure for their patients and 27(87%) considered that PET added to the therapeutic decision. The current treatment decision (clinical or revascularization) correlated with myocardial viability (p=0.006).

CONCLUSIONS: Coincidence imaging is a useful tool to help physicians in a difficult decision about the best treatment for patients with ischemic cardiomyopathy. Symptoms, electrocardiogram, ejection fraction and myocardial fibrosis area did not correlate with myocardium viability, so they should not be used to decide whether to perform a myocardial viability study or not.

Key words: Ischemic cardiomyopathy, myocardial viability, PET, coincidence system.

Positron Emission Tomography (PET) is a type of exam in Nuclear Medicine Assessment recently introduced in our country. Its use in Oncology, Neurology/Psychiatry and Cardiology is well documented in the world literature ^1-4. In our country, the experience with this type of exam is still a recent one, as the production of ¹⁸fluordesoxiglicose (¹⁸F-FDG), a radioisotope used in PET, started in 1999 ⁵.

As with any new technology, the introduction of a new diagnostic method can lead to two extremes: its overvalorization, with exaggerated use and lack of adequate assessment; or its underuse, due to the lack of clinical practice caused by diverse barriers, such as knowledge and trust of clinicians, the approval by health insurance companies and patients' access to public health services. Regarding PET, the its limitations include the high cost of the exam, the low availability of radioisotope-producing centers and adequate equipment. Currently, this imaging method is available only in the states of Sao Paulo and Rio de Janeiro (in the metropolitan cities) and in relatively few Nuclear Medicine Services.

Among the clinical applications of PET, it is noteworthy the assessment of myocardial viability, which is a very important topic considering its correlation with cardiac failure, a disease of epidemic proportions with almost 5 million people with this morbidity in the United States alone, and 550,000 new cases every year ⁶.

Among the patients who are admitted to the hospital with a primary diagnosis of cardiac failure, coronary disease is the most important etiological factor, being present in up to 70% of the cases^7,8. In a study carried out by the Mayo Clinic from 1979 to 1994, it was observed that 36% of the patients who survived an acute myocardial infarction (AMI) developed cardiac failure⁹.

The success of the thromboembolytic therapy and primary angioplasty has reduced the mortality by AMI. Nevertheless, many survivors of an AMI still develop left ventricular dysfunction ⁷.

Up to 50% of the regions showing Q waves at the electrocardiogram (ECG) or segmented dysfunction at the echocardiogram are potentially recoverable after the revascularization of this region, as there can be viable areas with hibernating or stunned myocardium mixed with fibrotic tissue¹⁰.

A meta-analysis with 3,088 patients from 24 myocardial viability studies showed that those patients who presented myocardial viability diagnosed by stress echocardiogram (STRESS ECHO), myocardial scintillography with thallium²⁰¹ or PET with ¹⁸F-FDG and who were submitted to revascularization presented a reduction in the annual mortality of 79.6% in comparison to those who presented viability but were not submitted to revascularization. The absence of myocardial viability did not determine a survival difference in patients submitted to clinical vs. surgical treatment^11,12.

When we consider that survival in individuals with severe ventricular dysfunction treated clinically is around 50% in a five-year period¹, this potential possibility of functional recovery can be significant for those patients who present cardiac failure, mainly because up to 50% of the patients waiting to undergo a cardiac transplant have ischemic cardiopathy⁷. On the other hand, the mortality rate within 30 days after the myocardial revascularization surgery in patients with left ventricular dysfunction can reach 20%¹. Thus, it is mandatory to identify the presence of viable myocardium in patients with ischemic cardiopathy and severe left ventricular dysfunction in order to verify which ones will indeed benefit from the myocardial revascularization.

The medical decision regarding a procedure to be implemented must be based on some mainstays such as the patient's clinical condition, when the risk of the clinical condition will be assessed and the cost-benefit of certain procedure; the patient's preferences regarding treatment; and the evidence related to the case, which include: clinical history data, physical examination and complementary test data, as well as information obtained through other scientific studies. The doctor's experience is the factor that will join and assess all this information, with the objective of reaching the most adequate procedure for the patient.

Regarding the role of complementary tests, at this time of medical costs and scientific evidence evidence-based cardiology the focus has been shifted from the observation of basic operational characteristics of a complementary test such as sensitivity, specificity and true predictive value ratio to the focus of the clinical impact, following the analysis of the test result on the medical procedure to be implemented.

There is plenty of evidence on the impact of PET on the management of patients with ventricular dysfunction of ischemic origin; however, the high cost of this technology regarding its initial investment as well as its maintenance has decreased its possibility of use, not only in our country but also in other centers around the world¹³.

Thus, in recent years, the conventional gamma-chamber started to be used in exams with ¹⁸F-FDG, resulting in the so-called hybrid PET-SPECT with a coincidence detection system, using a gamma-chamber with two detectors, which are configured at 180º ^14,15.

Therefore, the primary objective of this study is to evaluate the clinical impact, i.e., the influence on the decision-making of Positron Emission Tomography (PET) carried out by a Coincidence System with ¹⁸fluordesoxiglicose, to assess myocardial viability in patients with a previous history of acute myocardial infarction and left ventricular dysfunction. As secondary objectives, we aimed at establishing a correlation between the presence of myocardial viability and symptoms, ECG findings, left ventricle ejection fraction assessed by Gated SPECT and the area of fibrosis assessed by myocardial perfusion scintillography.

METHODS

A series of thirty-one consecutive patients of both genders, referred to the Nuclear Medicine and Molecular Imaging Service of Hospital Pró-Cardíaco were selected for undergoing a Positron Emission Tomography (PET) using a Coincidence System with ¹⁸fluordesoxiglicose (¹⁸F-FDG) in order to assess myocardial viability, according to the physician's decision, regardless of the present study, from September 2003 to November 2004. The research project was approved by the Review Boards of Hospital Pró-Cardíaco.

The inclusion criteria were: previous myocardial infarction history, with or without the presence of Q wave at the ECG, but with signs of segmental fibrosis at the myocardial perfusion scintillography, such as: hypouptake of the radioisotope at rest, associated to contractility alteration and myocardial thickening at the same region; a minimum period of three weeks after the acute myocardial infarction; presence of coronary atherosclerotic disease, documented through coronary angiography or the presence of risk factors for coronary atherosclerotic disease or previous history of myocardial revascularization; presence of at least 12% of myocardial fibrosis assessed by myocardial perfusion scintillography at rest using the Emory Cardiac Toolbox software; and systolic dysfunction of the left ventricle with an ejection fraction d" 40% quantified by Gated SPECT (Cedars Quantitative Gated SPECT) or presence of clinical signs of cardiac failure. We excluded patients with no history of acute myocardial infarction, those with left ventricle systolic dysfunction of non-ischemic etiology, fibrosis area < 12% at scintillography at rest, younger than 18 yrs and women of reproductive age with suspected or confirmed pregnancy.

Patients were submitted to clinical data collection. Cardiac failure symptoms were classified according to the New York Heart Association (NYHA) ¹⁶ and the presence of angina was classified according to the guidelines from the Canadian Cardiovascular Society (CCS)¹⁷.

A myocardial perfusion scintillography with 99mTc tetrofosmin (Myoview®) was carried out with the intravenous administration at rest of 740 MBq. The images were acquired between 45 and 90 min after the administration of the radioisotope by an E.cam Duet® (Siemens) gamma-chamber using two detectors with an angle of 90º between them, with a 64 X 64 matrix, 1.45 zoom and 32 projections of 20 seconds each, synchronized with the ECG (Gated SPECT), to allow the three-dimensional reconstruction and the measurement of the ejection fraction. The image processing was carried out by filtered backprojection with a Butterworth filter, with a cutoff of 0.5 and an order of 5. The images were then interpreted through the division of the left ventricle in 17 segments¹⁸; the quantification of the fibrosis area was performed using the Emory Cardiac Toolbox software and the ventricular function assessment by Gated SPECT, using the Cedars Quantitative Gated SPECT software.

Positron Emission Tomography and myocardial perfusion scintillography were carried out on different days. Patients had fasted for at least 4 hours, and the administration of 370 MBq of ¹⁸F-FDG intravenously was carried out with a capillary glycemia < 140 mg%. Non-diabetic patients were offered an oral overload of 50-75 mg of glucose 60 min before radioisotope administration. Capillary glycemia was monitored every 15 min. If the capillary glycemia was elevated 45-60 min after the glucose overload, regular insulin was administered i.v., as described in Chart 1¹⁹.

When capillary glycemia is kept between 110 and 140 md/dL after two consecutive measurements, the radioisotope is administered. As for diabetic patients, two solutions are prepared: one with 100 IU of insulin in 500 ml of saline solution and another with 500 mL of 20% glucose added to 20 mL of 10% potassium chloride. Each solution is infused into an upper extremity, as 4 mU/kg/min of insulin and 6 mg/kg/min of glucose. Capillary glycemia is measured every 10 min and the infusions are adjusted according to the glycemia level, aiming at keeping it between 110 and 140 mg/dL. When capillary glycemia is maintained within this range for two consecutive measurements, the radioisotope is administered²⁰. During the preparation for the exam, the patient is monitored by the unit nurse and physician. Data acquisition occurred 30 to 90 minutes after the administration of the radioisotope, in an E.cam Duet® (Siemens) gamma-chamber by coincidence system, with a 1-inch thick NaI crystal doped with Tl and detectors configured at 180º with no attenuation correction. The acquisition data are: 64 x 64 matrix, 1.45 zoom and 32 projections of 25 seconds each. The images were reconstructed together with the data obtained from the myocardial perfusion scintillography at rest, with an interactive reconstruction (OSEM) through a Gaussian filter, with a cutoff = 10. The images were analyzed regarding the presence of segments with presence or absence of glucose metabolism and the perfusion-metabolism mismatch area was quantified by the Emory Cardiac Toolbox software. The images were interpreted together with two other physicians from the Nuclear Medicine and Molecular Image Service of Hospital Pro-Cardiaco, both certified by the Brazilian Society of Nuclear Medicine. The presence of myocardial viability was considered when there was at least one myocardial segment with perfusion-metabolism discordance.

A clinical follow-up, ranging 2-14 months after the exam, was carried out by telephone and the patients were asked about the need to undergo revascularization, their current symptoms and use of medication.

The patients' physician answered a questionnaire that included the following items: type of treatment proposed before PET; the clinical situation that prompted the request for PET; the treatment proposed for the patient after the PET; whether PET modified or not the therapeutic strategy implemented after the exam, such as change from clinical treatment to myocardial revascularization treatment; and whether the PET result contributed for the decision-making, even in those cases where the therapeutic decision was not altered, but the physician's initial impression was confirmed by PET findings.

The statistical analysis was carried out by the following methods: Mann-Whitney (non-parametric test) to compare quantitative data between two groups; Fisher exact test to compare ratios (qualitative data) between two groups; significance level was set at 5%, i.e., there is statistical significance when p value is < 0.05.

RESULTS

General aspects: Clinical data of the studied population are shown in Table 1 and scintillography data are shown in Table 2. Numerical data were expressed as mean ± SD (minimum and maximal) and qualitative data as frequency and percentage.

Thumbnail

Evaluation of the clinical impact of PET on the therapeutic decision-making regarding PET results, we observed that 27 patients (87%) presented at least one myocardial segment with perfusion-metabolism discordance, suggesting viable myocardium. Graph I presents the division of the number of patients according to the number of viable segments.

When performing the correlation between the therapeutic decision-making and the presence of myocardial viability, we observed that none of the patients who did not present myocardial viability was referred to invasive therapy, whereas surgical or percutaneous revascularization was proposed for 21 of 27 (77.8%) of those who presented viability (p=0.006), showing that the group of patients with viable myocardium presented a significantly higher revascularization indication when compared to the group with no myocardial viability.

However, we observed that the presence of viable myocardium was not significant regarding the influence of PET on the change of therapeutic decision-making (p=0.086), i.e., the presence as well as the absence of viability was important for decision-making, although a slight tendency towards the association between viability and change of therapeutic option was noticed. Regarding the direct contribution of PET on decision-making, there was no analogous association with the presence of viability (p=0.55). From the analysis of these data, we observed that both results, namely presence or absence of viability, are taken into account by the physician and influence therapeutic decision-making.

When we analyze the current medical strategy regarding the choice between clinical treatment and invasive procedure, taking into account the number of viable segments observed at PET, we observe that patients who underwent revascularization showed, on average, 4.29 ± 2.47 viable segments, whereas the group who received clinical treatment had 1.9 ± 2.18 viable segments (p=0.011), indicating that a higher number of viable segments was significant for the invasive treatment choice. The same happens concerning the viable myocardium area, as there was an average area of 16.1% ±13.58% for those who underwent revascularization and 7.4% ± 8.95% for those who had clinical treatment.

Correlations between viability and clinical, electrocardiographic and scintillographic variables The presence or absence of symptoms (of cardiac or coronary failure) did not correlate with the detection of viable myocardium, given that, of 23 the symptomatic patients, 21 presented viable myocardium; however, among the 8 symptomatic patients, 6 of them also presented viability (p=0.26).

Data on the ECG at rest of 19 patients were available, and only one of these patients presented normal ECG; the remaining 18 were distributed as follows: 10 (55.5%) showed Q waves at the ECG, whereas 8 (44.5%) presented bundle branch block (right or left). The analysis of the presence of Q wave regarding the presence of viability was impaired by the small sample size; nonetheless, the fact that 9 patients who had Q waves at ECG also showed viability is noteworthy.

When we analyze the difference between the two groups (with and without viability) regarding ejection fraction by Gated SPECT and with fibrosis area assessed by the Emory Cardiac Toolbox, we observed no statistically significant difference between the two groups regarding these two variables, with p= 0.59 and p=0.90 for each group, respectively.

As for ejection fraction, the group that presented viability had a mean ejection fraction of 29.7%, whereas the group with no viability had 26.75%. Regarding fibrosis area, there was great similarity between both groups, with 38.04% of myocardial area with fibrosis at the scintillography at rest for the viability group and 38.75% in the group with no viability.

Follow-up None of the 4 patients with absence of viability underwent an invasive procedure, whereas of the 27 who presented viability, 13 were submitted to myocardial revascularization (7 angioplasties and 6 surgical procedures).

There was intention to treat in eight cases, but the treatment was not carried out due to the following reasons: in 3 cases, the coronary anatomy was difficult to reach; in one case, the patient died in the preoperative period, while waiting for revascularization; two patients could not undergo revascularization: one due to refractory cardiac failure and another due to structural restrictions of the hospital unit; in one case, the doctor intended to perform surgical revascularization; however, the small viable area was a negative aspect that went against the decision, when discussed with the surgical team, who considered the procedure risk/benefit ration, and as a result, the patient is in cardiac rehabilitation. Therefore, 62% of the patients for whom there was intention to treat with myocardial revascularization really underwent the procedure. The statistical analysis of these data was not possible due to the small number of cases in one of the groups.

DISCUSSION

In the real world, in addition to viability, the physician must consider other factors related to the patient when establishing the most adequate procedure; the coronary anatomy, clinical status and associated co-morbidities are included among them.

Some studies have demonstrated that between 31% and 39% of the patients undergo revascularization, regardless of the PET findings^21-24. Auerbach et al²⁵ showed us that 68% of the patients with 5 or more viable myocardial segments underwent revascularization (differently from PET results in 32% of the cases); as for those with a smaller number of viable segments (1 to 4), the rate of revascularization was 52% whereas patients with no viability presented a rate of 36% of revascularization. However, these conclusions came from the observation of the patients' clinical follow-up and not directly from inquiring doctors regarding their intention to treat.

In Oncology, the clinical impact of PET on patient management has been demonstrated by studies in which the physician answers questionnaires regarding the therapeutic decision following PET data^26-33.

In Cardiology, after a search conducted by the Internet, no study was found in literature describing such study model. Our study is original regarding this type of assessment of the clinical impact on myocardial viability, using PET in a gamma-chamber by the coincidence system.

Literature shows that, concerning the research on myocardial viability, there is a significant concordance between PET findings with a dedicated system and PET in a gamma-chamber by the coincidence system. Tian et al³⁴ showed that the general concordance was 93% and that PET sensitivity by the coincidence system was 92%. Hasegawa et al³⁵ showed that the coincidence system presents spatial resolution, measurement sensitivity and image quality superior to those obtained by gamma-chambers equipped with high-energy collimator; however, in order to become equivalent to dedicated PET, attenuation correction is a very important factor. One of the limitations of our study is that our equipment is not equipped with attenuation correction; nevertheless, the 1-inch crystal characteristics warrant excellent image quality.

The doctors participating in our study answered a questionnaire in which they indicated the proposed treatment before PET, what the indication for the exam was, and after it, what therapeutic approach had been adopted, and whether there had been a change of therapeutic choice due to PET results and if PET had directly influenced the decision-making.

We observed a significant adherence on the part of these doctors regarding PET results, with concordance between myocardial viability and therapeutic proposal. Nevertheless, not only the presence but also the absence of myocardial viability were useful for doctors, and had influenced decision-making, regardless of the number of viable segments and area of viable myocardium. Similarly, the number of myocardial segments and extension of viable myocardium influence the therapeutic choice.

Among the 21 doctors who indicated myocardial revascularization, only 13 of their patients actually underwent surgery, which corresponds to 62% of the patients. This means that 38% of the patients had a final therapeutic approach that was different from PET results and intention to treat, which is in accordance with the aforementioned studies^25,36-39.

This means that the presence of myocardial viability is not the sole determinant that leads to myocardial revascularization, as not all patients with viable myocardium are candidates to revascularization due to a number of reasons, as previously mentioned: the complex coronary anatomy, the patient's decision and the associated co-morbidities⁴⁰.

In our country, we must add to these issues the lack of infrastructure of some hospitals to perform complex procedures such as cardiac surgery, or the prolonged waiting period that many patients have to face while waiting for a revascularization, causing many planned procedures not to be performed. We faced all these situations in our series, but the small number of cases is not enough to allow us to draw conclusions on this issue.

It is possible to infer that PET had an impact on the management of patients with ischemic cardiopathy in this population; obviously, it is necessary to increase the number of cases and doctors in order to be able to make such assertion with precision.

In our study, we did not find a significant correlation between the presence of cardiac failure or angina symptoms with the presence of myocardial viability, in concordance with the studies by Di Carli et al⁴³ Thus, the presence of symptoms is not necessary to prompt the assessment of myocardial viability.

Unfortunately, we only had access to the ECG results of 19 patients, but we observed that almost all of them presented alterations (18/19 94.7%). Although a more accurate statistical analysis of these data was not feasible, we observed that the presence of Q wave at the ECG did not invalidate the finding of perfusion-metabolism discordance.

Schinkel et al⁴⁰, using dobutamine stress echocardiogram in 150 patients, found myocardial viability in 58% of the dysfunctional segments that showed Q wave at the ECG. Comparing the latter with segments that were dysfunctional but did not show Q wave at the ECG, we observed no significant difference regarding viability finding (p=0.2). Thus, myocardial viability can be either observed or not, regardless of ECG results.

The mean ejection fraction found in our population was low (29.3%), constituting a population with more severe left ventricular dysfunction.

Studies that assessed myocardial viability analyzed patients with ejection fraction < 40% and many reported a mean ejection fraction similar to ours ^23,41,42.

When comparing the ejection fraction between patients with and without myocardial viability, we did not find a significant difference between the two groups (p=0.59). It shows that myocardial viability can be either present or not, regardless of the degree of ventricular dysfunction. These findings are in accordance with those by Di Carli et al⁴³, who suggest that myocardial viability assessment is useful, even in patients with severe ventricular dysfunction.

We believe that myocardial viability assessment must be carried out, even in patients with very low ejection fractions, as they can benefit from the procedure. We mention one of our patients who presented EF at rest of 13% and the study with ¹⁸F-FDG showed a viable myocardium area of 19%.

The study by Hurrell et al⁴⁴ of 1,224 patients showed, during a 2-year follow-up period, that patients with myocardial fibrosis area at rest > 12% of the myocardium, measured by scintillography, present a worse prognosis than those with a residual fibrosis area < 12% (p=0.003).

In our population, we found a mean fibrosis area of 38.1%. This means that the population studied presents an even higher risk for cardiac events. The possibility of finding myocardial viability can offer them the chance to modify the natural history of ischemic cardiomyopathy in this setting.

When we correlate the area of fibrosis with myocardial viability detection, we did not find any difference between the groups with and without viability regarding fibrosis extension (p=0.9). Both groups presented a mean fibrosis area > 38%, i.e., an extensive fibrosis area. This finding shows that it is possible to find viable myocardium even in patients with extensive fibrosis areas.

Considering our results, we can conclude that Positron Emission Tomography by Coincidence System had a clinical impact on therapeutic decision-making in this group of patients with ischemic cardiopathy after myocardial infarction. The presence of symptoms, the ECG, ejection fraction, and the myocardial fibrosis area did not correlate with the presence of PET viability in the studied population.

One of the limitations of our study is its small sample size, which does not allow conclusive assertions to be drawn from its results. The number of patients has to be increased or further studies must be carried out in order to confirm the results obtained. The study did not assess patients' expectations and values, which are factors that can influence therapeutic procedures. This work was carried out by highly specialized professionals in the Cardiology area, which might have influenced the results obtained.

No potential conflict of interest relevant to this article was reported.

REFERENCES

5. Cyclotron Accelerators Center.[web site on the Internet].São Paulo:IPEN;1999.[cited 2004 Nov 10].Available from:http://www.ipen.br/biblioteca/progress/cyclotron.htm

Received on 02/23/05

Accepted on 07/25/05

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30. Seltzer MA, Yap CS, Silverman DH, Meta J, Schiepers C, Phelps ME et al. The impact of PET on the management of lung cancer: the referring physician's perspective. J Nucl Med 2002; 43: 752-6.
31. Grahek D, Montravers F, Mayaud C , Regnard JF, Kerrou K, Younsi N et al. Positron emission tomography (PET) with 18F-FDG in bronchopulmonary cancer and its impact on medical decision at the time of the diagnosis, staging or recurrence evaluation. Rev Pneumol Clin .2001; 57: 393-403.
32. Kantorova I, Lipska L, Belohlvek O , Visokai V, Trubac M, Schneiderova M. Routine 18F-FDG PET preoperative staging of colorectal cancer: comparison with conventional staging and its impact on treatment decision making. J Nucl Med. 2003; 44: 1784-88.
33. Herder GJ, Van Tinteren H, Comans EF , Holkstra OS, Teule GJ, Postmus PE et al. Prospective use of serial questionnaires to evaluate the therapeutic efficacy of 18F-fluordeoxygluse (FDG) positron emission tomography (PET) in suspected lung cancer. Thorax .2003; 58: 47-51.
34. Tian M, Koyama K, Zhang H , Oriuchi N, Higuchi T, Endo K. Assessment of myocardial viability with a positron coincidence gamma camera using fluordeoxyglucose in comparison with dedicated PET. Nucl Med Commun .2003; 24: 367-74.
35. Hasegawa S, Uehara T, Yamaguchi H, Fujino K, Kusuoka H, Hori M et al. validity of ¹⁸F-fluorodeoxyglucose Imaging with a dual-head coincidence gamma camera for detection of myocardial viability. J Nucl Med .1999; 40: 1884-92.
36. Lee, K, Marwick TH, Cook S , Go RT, Fix JS,James KB et al. Prognosis of patients with left ventricular dysfunction, with and without viable myocardium after myocardial infarction:relative efficacy of medical therapy and revascularization Circulation 1994; 90: 2687-94.
37. Di Carli MF, Davidson M, Little R , Khannaady FV, Brunken RC. Value of metabolic imaging with positron emission tomography for evaluating prognosis in patients with coronary artery disease and left ventricular dysfunction. Am J Cardiol .1994; 73: 527-33.
38. Eitzman D, Al-Aouar Z, Kanter HL, Vom Dahl J, Kirsch M, Deeb GM et al. Clinical outcome of patients with advanced coronary artery disease. J Am Coll Cardiol .1992; 20: 559-65.
39. Yoshida K, Gould LK. Quantitative relation of myocardial infarction size and myocardial viability by positron emission tomography to left ventricular ejection fraction and 3-year mortality with and without revascularization. J Am Coll Cardiol 1993; 22: 984-97.
40. Schinkel AFL, Bax JJ, Boersma E , Elhendy A, Vourvouri EC, Roelandt JR et al. Assessment of residual myocardial viability in regions with chronic electrocardiographic Q-wave infarction. Am Heart J.2002; 144: 865-9.
41. Marwick TH, Zuchowskic C, Lauer MS , Secknus MA,Williams J, Lytle BW. Functional status and quality of life in patients with heart failure undergoing coronary bypass surgery after assessment of myocardial viability. J Am Coll Cardiol. 1999; 33: 750-8.
42. Beanlands RSB, Ruddy TD, deKemp RA , Iwanochko RM, Coates G, Freem,na M et al. Positron emission tomography and recovery following revascularization (PARR-1): the importance of scar and the development of a prediction rule for the degree of recovery of left ventricular function. J Am Coll Cardiol. 2002; 40: 1735-43.
43. Di Carli MF, Maddahi J, Rokhsar SBA , Schelbert HR, Bianco-Batles D, Brunken RC et al. Long-term survival of patients with coronary artery disease and left ventricular dysfunction: implications for the role of myocardial viability assessment in management decisions. J Thorac Cardiovasc Surg .1998; 116: 997-1004.
44. Hurrell DG, Milavetz J, Hodge DO, Gibbons RJ. Infarct size determination by technetium 99m sestamibi single-photon emission computed tomography predicts survival in patients with chronic coronary artery disease. Am Heart J .2000; 140: 61-6.

Mailing Address:

Renata Christian Martins Felix

Rua General Polidoro, 192 Botafogo

22280-000 - Rio de Janeiro, RJ - Brazil

E-mail:

renatafelix@cardiol.br ou

medicina.nuclear@procardiaco.com.br

Publication Dates

Publication in this collection
29 May 2006
Date of issue
May 2006

History

Accepted
25 July 2005
Received
23 Feb 2005

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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[26] 27. Meta J, Seltzer M, Schiepers C , Silverman DH, Ariannejad M, Gamhir SS et al. Impact of 18F-FDG PET on managing patients with colorectal cancer: the referring physician´s perspective. J Nucl Med .2001; 42: 586-90.

[27] 28. Yap CS, Seltzer MA, Schiepers C ,Gambhir SS, Rao J, Phelps ME et al. Impact of whole-body 18F-FDG PET on staging and managing patients with breast cancer: the referring physician's perspective. J Nucl Med .2001; 42: 1334-7.

[28] 29. Schoder H, Meta J, Yap C , Ariannejad M, Rao J, Phelps ME et al. Effect of whole-body 18F-FDG PET imaging on clinical staging and management of patients with malignant lymphoma. J Nucl Med .2001; 42: 1139-43.

[29] 30. Seltzer MA, Yap CS, Silverman DH, Meta J, Schiepers C, Phelps ME et al. The impact of PET on the management of lung cancer: the referring physician's perspective. J Nucl Med 2002; 43: 752-6.

[30] 31. Grahek D, Montravers F, Mayaud C , Regnard JF, Kerrou K, Younsi N et al. Positron emission tomography (PET) with 18F-FDG in bronchopulmonary cancer and its impact on medical decision at the time of the diagnosis, staging or recurrence evaluation. Rev Pneumol Clin .2001; 57: 393-403.

[31] 32. Kantorova I, Lipska L, Belohlvek O , Visokai V, Trubac M, Schneiderova M. Routine 18F-FDG PET preoperative staging of colorectal cancer: comparison with conventional staging and its impact on treatment decision making. J Nucl Med. 2003; 44: 1784-88.

[32] 33. Herder GJ, Van Tinteren H, Comans EF , Holkstra OS, Teule GJ, Postmus PE et al. Prospective use of serial questionnaires to evaluate the therapeutic efficacy of 18F-fluordeoxygluse (FDG) positron emission tomography (PET) in suspected lung cancer. Thorax .2003; 58: 47-51.

[33] 34. Tian M, Koyama K, Zhang H , Oriuchi N, Higuchi T, Endo K. Assessment of myocardial viability with a positron coincidence gamma camera using fluordeoxyglucose in comparison with dedicated PET. Nucl Med Commun .2003; 24: 367-74.

[34] 35. Hasegawa S, Uehara T, Yamaguchi H, Fujino K, Kusuoka H, Hori M et al. validity of ¹⁸F-fluorodeoxyglucose Imaging with a dual-head coincidence gamma camera for detection of myocardial viability. J Nucl Med .1999; 40: 1884-92.

[35] 36. Lee, K, Marwick TH, Cook S , Go RT, Fix JS,James KB et al. Prognosis of patients with left ventricular dysfunction, with and without viable myocardium after myocardial infarction:relative efficacy of medical therapy and revascularization Circulation 1994; 90: 2687-94.

[36] 37. Di Carli MF, Davidson M, Little R , Khannaady FV, Brunken RC. Value of metabolic imaging with positron emission tomography for evaluating prognosis in patients with coronary artery disease and left ventricular dysfunction. Am J Cardiol .1994; 73: 527-33.

[37] 38. Eitzman D, Al-Aouar Z, Kanter HL, Vom Dahl J, Kirsch M, Deeb GM et al. Clinical outcome of patients with advanced coronary artery disease. J Am Coll Cardiol .1992; 20: 559-65.

[38] 39. Yoshida K, Gould LK. Quantitative relation of myocardial infarction size and myocardial viability by positron emission tomography to left ventricular ejection fraction and 3-year mortality with and without revascularization. J Am Coll Cardiol 1993; 22: 984-97.

[39] 40. Schinkel AFL, Bax JJ, Boersma E , Elhendy A, Vourvouri EC, Roelandt JR et al. Assessment of residual myocardial viability in regions with chronic electrocardiographic Q-wave infarction. Am Heart J.2002; 144: 865-9.

[40] 41. Marwick TH, Zuchowskic C, Lauer MS , Secknus MA,Williams J, Lytle BW. Functional status and quality of life in patients with heart failure undergoing coronary bypass surgery after assessment of myocardial viability. J Am Coll Cardiol. 1999; 33: 750-8.

[41] 42. Beanlands RSB, Ruddy TD, deKemp RA , Iwanochko RM, Coates G, Freem,na M et al. Positron emission tomography and recovery following revascularization (PARR-1): the importance of scar and the development of a prediction rule for the degree of recovery of left ventricular function. J Am Coll Cardiol. 2002; 40: 1735-43.

[42] 43. Di Carli MF, Maddahi J, Rokhsar SBA , Schelbert HR, Bianco-Batles D, Brunken RC et al. Long-term survival of patients with coronary artery disease and left ventricular dysfunction: implications for the role of myocardial viability assessment in management decisions. J Thorac Cardiovasc Surg .1998; 116: 997-1004.

[43] 44. Hurrell DG, Milavetz J, Hodge DO, Gibbons RJ. Infarct size determination by technetium 99m sestamibi single-photon emission computed tomography predicts survival in patients with chronic coronary artery disease. Am Heart J .2000; 140: 61-6.

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