Recent eLetters

Dear Editors:

We are writing in regards to the paper entitled "Quantitative myocardial perfusion analysis using multi-row detector CT in acute myocardial infarction" that is recently published in the April 2012 issue of Heart. We would like to congratulate the authors for a very interesting study that has used all the advanced techniques available in the GE Healthcare CT Perfusion research version software. We are the core laboratory that develop and validate the techniques in that version of the software and are very pleased that they are being used successfully in their work. Instead of references #13-16 in their paper, the correct references that detail our work implemented in the software are as follows:

1. So A et al. Beam hardening correction in CT myocardial perfusion measurement. Phys Med Biol 2009;54(10):3031-3050

2. So A et al. Quantitative myocardial perfusion measurement using CT Perfusion: a validation study in a porcine model of reperfused acute myocardial infarction. Int J Cardiovasc Imaging. Epub 2011 Jul 29

3. So A et al. Non-invasive assessment of functionally relevant coronary artery stenoses with quantitative CT perfusion: preliminary clinical experiences. Eur Radiol 2012;22(10):39-50 Epub 2011 Sep 21

In particular, the beam hardening correction method in the CT Perfusion research version software is based on our work previously published in 2009 (see #1 above) rather than the work of Kitagawa et al as referenced in the paper.

We hope this clarification would prevent confusion in the mind of readers who read the paper and are stimulated to pursue quantitative myocardial perfusion research.

Best regards,

Aaron So, PhD, Associated Scientist, Lawson Health Research Institute, London, Ontario, Canada

Ting-Yim Lee, PhD, FCCPM, CIHR-GE Healthcare Chair in Functional Imaging; Director, PET/CT Research, Lawson Health Research Institute; Scientist, Robarts Research Institute; Professor, Medical Biophysics, Oncology, Medical Imaging, Western University, London, Ontario, Canada

Conflict of Interest:

T.-Y. Lee has a CT Perfusion software licensing agreement with GE Healthcare, and receives research grant support from GE Healthcare, Astra Zeneca and Celgene. A. So has no disclosure.

Versteylen et al (1) recently evaluated several area at risk (AAR) methods in patients with acute ST elevation myocardial infarction (STEMI) using 4 physiologic principles, and concluded that cardiac magnetic resonance imaging (CMRI) methods out-perform angiographic methods, which are better than electrocardiographic (ECG) methods. However this study utilized the antiquated Aldrich score, rather than the updated ECG index, described by Wilkins et al (2).

The Aldrich score is based upon the extent of inferior ST elevation and total number of leads with ST elevation in anterior infarcts. Recent studies have shown that it is an unstable marker of AAR (3) and correlates poorly with SPECT imaging (4). The modified score by Wilkins et al (2), incorporates the number of leads with abnormal Q waves, ST elevation and/or peaked T waves in anterior infarcts, and the extent of excess Q wave duration and inferior ST elevation in inferior infarcts. Compared with the Aldrich score, this method produced better correlations with QRS- derived final infarct size (2).

To further evaluate the Wilkins method, we compared Aldrich and Wilkins AAR estimates in 47 acute STEMI patients who had undergone CMRI with delayed hyperenhancement, and observed the following, as regards conformity to the 4 physiologic principles proposed by these authors (1):

1. For the concept that AAR is always ? infarct size (IS), the Wilkins method conformed in 76% of patients, compared to 59% for the Aldrich score.

2. In patients with transmural infarcts, Bland-Altman plots showed better agreement between AAR and IS using the Wilkins method (95% CI - 18.42 to 8.125), compared to Aldrich score (95% CI -18.54 to 15.37).

3. Increasing correlation between AAR size and IS was observed with increasing infarct transmurality for the Wilkins method but not the Aldrich score.

4. In the correlation of myocardial salvage and mean transmurality, 78% of patients were within the ?30% margin of the inverse 'line of identity' using the Wilkins method as compared to 60% for the Aldrich score.

Accordingly, compared with its antecedent ECG index, the Wilkins method better fulfils the principles outlined by Versteylen et al, perhaps to degree equivalent to angiographic AAR methods.

References: 1. Versteylen MO, Bekkers SC, Smulders MW, et al. Performance of angiographic, electrocardiographic and MRI methods to assess the area at risk in acute myocardial infarction. Heart 2012;98:109-15. 2. Wilkins ML, Maynard C, Annex BH, et al. Admission prediction of expected final myocardial infarct size using weighted ST-segment, Q wave, and T wave measurements. J Electrocardiol 1997;30:1-7. 3. Bouwmeester S, van Hellemond IE, Maynard C, et al. The stability of the ST segment estimation of myocardial area at risk between the prehospital and hospital electrocardiograms in patients with ST elevation myocardial infarction. J Electrocardiol 2011;44:363-9. 4. Christian TF, Gibbons RJ, Clements IP, Berger PB, Selvester RH, Wagner GS. Estimates of myocardium at risk and collateral flow in acute myocardial infarction using electrocardiographic indexes with comparison to radionuclide and angiographic measures. J Am Coll Cardiol 1995;26:388- 93.

Conflict of Interest:

None declared

Young-Hoon Jeong, MD, PhD,1,2 Kevin P Bliden , MBA,1 Yongwhi Park, MD, PhD,2 Udaya S. Tantry, PhD,1 Paul A. Gurbel, MD1

1Sinai Center for Thrombosis Research, Baltimore, Maryland; and 2Division of Cardiology, Department of Internal Medicine, Gyeongsang National University Hospital, Jinju, Korea.

The study by Breet et al.1 supported our previous suggestion that a cutoff of aspirin reaction units (ARU) >550 was too high to identify high on-treatment platelet reactivity (HPR).2 The cutoff defined by the highest quartile (461 ARU) from our study2 is remarkably similar to the 454 ARU cutoff value associated with 1-year outcomes in the Breet et al. study.1 Moreover, across ARU quartiles, reactivity to ADP and collagen significantly increased.2

In a new analysis of 558 patients undergoing percutaneous coronary intervention during aspirin and clopidogrel therapy, we could observe that 5microM ADP- and 0.5mg/mL arachidonic acid (AA)-induced aggregation correlated well (r =0.625) (Figure A). In addition, receiver-operating characteristics curve analysis showed that 19.5% AA-induced aggregation corresponded to 5microM ADP-induced aggregation >46% cutoff for HPR3 (Figure B). These data agree strongly with the HPR cutoff of 20.0% AA- induced aggregation associated with 1-year outcomes in the Breet et al. study.1 Moreover, patients with HPR to ADP had a 2.4-fold greater prevalence of HPR to AA, and there was high concordance between two criteria (~74%) (Figure A), suggesting that HPRs as determined by ADP- and AA-induced platelet aggregation may not be different indicators of the risk stratification, but identify a global phenotype of hyperreactive platelets.

It is a matter of debate whether the VerifyNow-ASP assay can determine reliably the extent of AA-induced aggregation. In the Aspirin- Induced Platelet Effect (ASPECT) study,4 the estimation of HPR to AA was highly assay-dependent, and no significant correlations in HPR to AA existed between AA-induced LTA and VerifyNow-ASP. The presence of uninhibited cyclooxygenage-2 in whole blood that contributed to thromboxane A2 production may explain different prevalence of HPR to AA in VerifyNow-ASP as compared with LTA.

To date, no convincing data are available regarding the utility of measuring platelet response to multiple agonists in stratifying the risk for ischemic events. High platelet reactivity to multiple agonists may not be due to independent responses, but rather indicate a global high platelet reactivity phenotype.2 Whether personalized antiplatelet therapy based on platelet response to multiple agonists is more beneficial than measuring response to a single agonist deserves further investigation.

REFERENCES

1. Breet NJ, van Werkum JW, Bouman HJ, et al. High on-treatment platelet reactivity to both aspirin and clopidogrel is associated with the highest risk of adverse events following percutaneous coronary intervention. Heart 2011;97:983-90.

2. Dichiara J, Bliden KP, Tantry US, et al. Platelet function measured by VerifyNowTM identifies generalized high platelet reactivity in aspirin treated patients. Platelets 2007;18: 414-23.

3. Bonello L, Tantry US, Marcucci R, et al. Working Group on High On -Treatment Platelet Reactivity. Consensus and future directions on the definition of high on-treatment platelet reactivity to adenosine diphosphate. J Am Coll Cardiol 2010;56:919-33.

4. Gurbel PA, Bliden KP, DiChiara J, et al. Evaluation of dose- related effects of aspirin on platelet function: results from the Aspirin-Induced Platelet Effect (ASPECT) study. Circulation 2007;115:3156- 64.

We want to attach a figure file.

Conflict of Interest:

HPRs as determined by ADP- and AA-induced platelet aggregation may not be different indicators of the risk stratification, but identify a global phenotype of hyperreactive platelets. In addition, It is a matter of debate whether the VerifyNow-ASP assay can determine reliably the extent of arachdonic acid-induced aggregation.

West and colleagues'[1] recently published randomised controlled trial (RCT) exemplifies successful failure. Because and not despite of its null findings and flaws, RAMIT provides lessons for the future of prevention. Skeptics and proponents of traditional hospital-based cardiac rehabilitation (CR) should not use the study's findings or flaws to defend their respective positions but harness its failure constructively for innovation in designing more accessible and effective services.

Regarding doubts raised by the findings over the benefits of CR in the modern age, commendably and post-hoc, the study was powered to detect differences in mortality at 7-9years and in all likelihood risk factors at one-year. Yet, its failure to find benefits in these outcomes potentially points to the need for CR interventions to evolve from time-limited, exercise-focused programmes into more accessible and individually tailored ones. Such programmes could equally address all modifiable risk factors,[2] as necessary, and include long-term follow-up with ongoing support.[3]

While the RAMIT design was originally a large-scale RCT it was ultimately flawed because it was stopped early for unclear reasons having enrolled around 22% (n=1813) of the targeted sample size in approximately 3years. Also, over 20% of the intervention group dropped out and did not complete the rehabilitation programme and any contamination among controls is unclear. Such barriers are common amongst CR trials and clinical programmes and suggest that flexible programmes that overcome indifference, transport and work-related issues are important to pursue and develop.

RAMIT's findings also highlight the need for better description of the intervention. As CR programmes are complex interventions, CONSORT recommends they be described comprehensively with "precise details" of content. This not only improves trial quality but also uptake of evidence by clinicians.[4] In RAMIT, specific content of the intervention for each risk factor and corresponding behaviour change techniques used are poorly described.

Finally, the benefits of trials should not be reduced to headline effects. Findings, whether positive or negative, can yield useful insights to improve interventions and methodology. A focus on increasing participation in evidence-based risk factor management strategies that are individualised and multidimensional will help researchers keep pace with advances in medical management.

References 1. West RR, Jones DA, Henderson AH. Rehabilitation after myocardial infarction trial (RAMIT): multi-centre randomised controlled trial of comprehensive cardiac rehabilitation in patients following acute myocardial infarction. Heart 2012 (Published on December 22, 2011 as 10.1136/heartjnl-2011-300302). 2. Wood DA, Kotseva K, Connolly S, et al, on behalf of EUROACTION Study Group. Nurse-coordinated multidisciplinary, family-based cardiovascular disease prevention programme (EUROACTION) for patients with coronary heart disease and asymptomatic individuals at high risk of cardiovascular disease: a paired, cluster randomised controlled trial. Lancet 2008;371:1999-2012. 3. Redfern J, Maiorana A, Neubeck L, Clark AM, Briffa T. Achieving coordinated Secondary Prevention of coronary heart disease for All in Need (SPAN). Int J Cardiol 2011;146(1):1-3. 4. Clark AM, Redfern J, Thompson D, Briffa T. More data, better data or improved evidence translation: what will improve cardiovascular outcomes? Int J Cardiol 2012;155:347-349.

Conflict of Interest:

None declared

Dear Editor,

We read with interest, but also great concern, the paper by West, et al.1 on their multi-centre randomized cardiac rehabilitation study, suggesting negligible results. This study was covered in the Belgian press and already led to questions about further reimbursement of such multi- disciplinary programs. We agree that re-evaluation of cardiac rehabilitation in the era of early revascularisation and thoroughly changed secondary prevention, is timely. However, this study does not involve a standard exercise training component. Patients only trained once a week or biweekly; this is nowhere near the general recommendations for physical activity in primary or secondary prevention. Intensity, modality and duration of training sessions are not described, and exercise testing pre and post rehabilitation to assess treatment effect is lacking. Also, significantly fewer patients were exercising after 1 year, suggesting exercise underdosage. We disagree with their presumption that improved secondary prevention precludes multi-disciplinary rehabilitation programs. The recently published EUROASPIRE III showed that cardiovascular prevention is still poorly implemented in daily practice. West et al. themselves reported a suboptimal preventive approach; only 54-62% of patients were taking a statin or beta-blocker at follow-up. The authors also failed to mention two recent studies demonstrating that cardiac rehabilitation led to a 45% reduction in long-term mortality in a registry of 2395 post-PCI patients.2 In a registry of 18809 patients with acute coronary syndrome, failure to comply with lifestyle and exercise recommendations was associated with an early almost 4-fold increased risk of adverse cardiovascular events.3 These patients were extremely well treated in terms of pharmacological prevention. The authors also concluded that cardiac rehabilitation had no effect on psychological morbidity or quality of life, but generic measures, such as the SF36, may have lacked sensitivity to detect actual changes in patient-reported outcomes. Previous work has shown that cardiac rehabilitation has a significant beneficial effect on psychological morbidity.4 To our opinion, the most important conclusion from this study is incorporated in the last line of the abstract; maybe it is time to re- think cardiac rehabilitation in the UK.

References

1. West RR, Jones DA, Henderson AH. Rehabilitation after myocardial infarction trial (RAMIT): multi-centre randomised controlled trial of comprehensive cardiac rehabilitation in patients following acute myocardial infarction. Heart 2011; doi:10.1136/heartjnl-2011-300302 2. Goel K, Lennon RJ, Tilbury RT et al. Impact of cardiac rehabilitation on mortality and cardiovascular events after percutaneous coronary intervention in the community. Circulation 2011;123:2344-2352. 3. Chow CK, Jolly S, Rao-Melacini P et al. Association of diet, exercise, and smoking modification with risk of early cardiovascular events after acute coronary syndromes. Circulation 2010;121:750-758. 4. Denollet J, Brutsaert DL. Reducing emotional distress improves prognosis in coronary heart disease: 9-year mortality in a clinical trial of rehabilitation. Circulation 2001;104:2018-2023.

Conflict of Interest:

None declared