Recent eLetters

Dear Editor

I read with great interest the editorial written by Zaman et al. The paper has also highlighted that it is very difficult in any ethnic group to understand all unmeasured socioeconomic variables which affect overall cardiovascular risk.

Some unmeasured variable potentially could be:

1) Level of education of parents in the family. 2) Profession of father and mother. 3) Financial status of the family. 4) Diet - Personal liking of fast food in the family. Very difficult to measure, however previous research has shown that fast food is often preferred in lower socio-economical class [1]. Also, generally speaking Asian food can vary in its saturated fat content depending upon personal preferences. This will directly affect cardiovascular risk in that population. 5) Location - For example, do Asians in London have better lifestyles than those living in Glasgow? And does this effect overall cardiovascular risk?

In my opinion, Asian community educational programmes geared to healthy lifestyles would be imperative to overall reduce the burden of cardiovascular disease in this group in the UK.

This could potentially include interactive sessions on -

1) Healthy Asian Cooking 2) Dancing (Bollywood/Hollywood) 3) Organised social group Country Walks 4) Talks on various diseases like Diabetes, Obesity, heart attack, risk factors for it. 5) Lastly, they should also know the fact - They are at higher risk of heart attack than any other ethnicity in the UK!

Hopefully, with education we can reduce the overall burden of CAD in Asian population in the UK.

Reference:

1. Smoyer-Tomic K.E., Spence J.C., Raine K.D., Amrhein C., et al. The association between neighborhood socioeconomic status and exposure to supermarkets and fast food outlets (2008) Health and Place, 14 (4), pp. 740-754.

Conflict of Interest:

None declared

to the editor: Spratt and colleagues describe two cases in which they state that performing a Computed Tomography coronary angiography (CTCA) prior to alcohol septal ablation (ASA) may aid in the selection of the appropriate septal branch for ablation and patients suitable for ASA (1). Visualisation of a dominant septal perforator and its course in the myocardium with CTCA has been described previously (2). Importantly, CTCA has three important limitations being that it is unable to visualise due to limitation of resolution smaller proximal septal branches that can be the target vessel, that it is unable to visualise the perfusion area of the septum and that it cannot display the area of maximal flow acceleration. The combination of coronary angiography and contrast echocardiography has been shown to be superior for these purposes (3) and we therefore believe that performing additional CTCA prior to ASA does not give extra information.

reference 1) Spratt JC, Langrish JP. Identifying the target septal perforator prior to alcohol septal ablation in hypertrophic obstructive cardiomyopathy: a new application for computed tomography coronary angiography. Heart 2011; 97: 1718-1719. 2) Brinjikji W, Harris SR, Froemming AT, Christensen KN, Lachman N, Araoz PA. Descriptive anatomy of the dominant septal perforators using Dual Source CT angiography. Clin Anat 2010; 23(1): 70-8. 3) Faber L, Seggewiss H, Gleichmann U. Percutaneous septal myocardial ablation in hypertrophic obstructive cardiomyopathy: Results with respect to intraprocedural myocardial contrast echocardiography. Circulation 1998; 98: 2415-2421.

Conflict of Interest:

None declared

I read with interest Harinstein et al's review of clinical assessment in acute heart failure syndromes (AHFS) . Initial assessment of AHFS included evaluation of important prognostic factors which influence treatment such as the presence of atrial fibrillation, acute pulmonary oedema and renal function. This is in accordance with the 6 axis model described by Professor Gheorghiade. An important factor in the 6 axis model which has been neglected is the role of blood pressure in the presentation and evaluation of AHFS. Blood pressure plays a critical role in the prognosis of acute heart failure and should be a central consideration in management decisions. Previous work by Prof Gheorghiade describes the central role of blood pressure in acute heart failure. Blood pressure is an independent predictor of mortality and morbidity in heart failure. AHFS can present with low, normal and high blood pressure and each of these groups have different pathophysiology and respond differently to treatment. It is important to distinguish between them in the evaluation of AHFS. High blood pressure in AHFS tends to be due to a reactive hypertension caused by high sympathetic tone whereas low blood pressure reflects poor cardiac output . Studies have shown that elevated systolic blood pressure (SBP) is common in patients hospitalized with AHFS. These patients have a lower post-discharge mortality, lower rates of rehospitalisation and shorter duration of stay that those with low systolic blood pressure. However they also have a increased risk of morbid events. It is hypothetised that blood pressure may distinguish those with early or mid stage disease (high SBP) from those with advanced disease (low SBP) . Congestive symptoms were more likely in high blood pressure at admission however during discharge low SBP had more congestive symptoms. Patients with high blood pressure may respond to heart failure treatment differently to low SBP however high blood pressure in AHFS is underrepresented in clinical trials of heart failure drugs. Use of ACE inhibitors and Beta blockers in these patients may have beneficial anti- hypertensive effect whereas they are less used in heart failure with hypotension. Hypotension may represent low cardiac output and maintaining adequate blood pressure is a treatment priority in the management of these types of AHFS. High SBP had better response to treatment however the re- hospitalisation rates and risk of morbid events were similar to low SBP. Better treatment response in high SBP gave physician a false sense of security that these patients were not as ill as hypotensive AHFS. This may have resulted in less aggressive management. There were lower rates of left ventricular function assessment and aldosterone use in high SBP. Acute heart failure is often inadequately managed in hospitals resulting in poor prognosis and re-hospitalisation. One of the factors influencing good management is careful evaluation of blood pressure. The role of this important factor is often poorly understood and underestimated. Yet it is a clinical feature which makes a substantial difference to treatment response.

Harinstein M E, Flaherty J D, Fonarow G C, Mehra M R, Lang R M, Raymond K J, Cleland J G, Knight B P, Pang P S, Bonow R O, GHEORGHIADE M Clinical assessment of acute heart failure syndromes: emergency department through the early post-discharge period Heart 2011 97:1607-1618; doi:10.1136/hrt.2011.222331

Gheorghiade M, Abraham W T, Albert N M, Greenberg B H, O'Connor C, Yancy C W, Young J B, Fonorow G C, Systolic Blood Pressure at Admission, Clinical Characteristics, and Outcomes in Patients Hospitalized With Acute Heart Failure JAMA. 2006;296(18):2217-2226. doi: 10.1001/jama.296.18.2217

Gheorghiade M, Abraham WT, Albert NM, et al., OPTIMIZE-HF Investigators and Coordinators. Systolic blood pressure at admission, clinical characteristics, and outcomes in patients hospitalized with acute heart failure. JAMA. 2006;296(18):2217-2226.

Flaherty JD, Bax JJ, De Luca L, et al., Acute Heart Failure Syndromes International Working Group. Acute heart failure syndromes in patients with coronary artery disease early assessment and treatment. J Am Coll Cardiol. 2009;53(3):254-263

Gheorghiade M, Zannad F, Sopko G, et al. Acute heart failure syndromes: current state and framework for future research. Circulation.2005;112:3958

Conflict of Interest:

None declared

To the Editor: We read with interest the paper by van Engelen et al.,1 analysing the prevalence of 22q11.2 deletion syndrome (22q11.2DS) in adults with tetralogy of Fallot (TOF) and with pulmonary atresia(PA)/ventricular septal defect (VSD). We agree with the experience that many adult patients with TOF have not been tested for 22q11.2DS in the past, so that awareness of the syndrome is needed among clinicians who care adults with congenital heart defects (CHDs). Nevertheless, we disagree to introduce as general practice the large-scale screening of all TOF patients irrespective of their clinical phenotype. Personal experience in paediatric patients with 22q11.2DS has evidenced that the deletion is virtually never found in non-syndromic patients with conotruncal defects.2 In addition, it has been evidenced that distinct subtypes of conotruncal heart defects are likely to be found in association with 22q11.2DS. In regard to TOF, patients with 22q11.2DS have often right/cervical aortic arch with/without aberrant left subclavian artery, hypoplasia or absence of the infundibular septum, absence of the pulmonary valve, and hypoplasia and discontinuity of the pulmonary arteries.2 Among children with TOF and PA, the 35% is carrying a 22q11.2DS, and distinctive recognizable patterns of CHDs include major aorto-pulmonary collateral arteries, sometimes with discontinuity of the pulmonary arteries.2 The review of the literature about clinical characteristics of adults with 22q11.2DS is showing that extracardiac anomalies can help clinician to suspect 22q11.2DS.3 Particularly, previous series reported that facial anomalies can be detected in 99-100% of the cases, ranging from subtle to characteristic. Additional evidenceable signs include hypernasal speech (90%), intellectual disability of any degree and/or learning difficulties (93-97%). The rare occurrence of extremely mild clinical expression of 22q11.2DS in a parent of an affected child can now be explained with the molecular mechanisms of genetic compensation (presence of a 22q11.2 deletion on one chromosome and 22q11.2 duplication on the other allele of chromosome 22).4 In conclusion, the search for 22q11.2DS is important in adult patients with TOF and with PA/VSD, since recognition of the syndrome has clinical and reproductive implications, but genetic testing, in our opinion, should be reserved to patients with associated "classic" or "subtle" extracardiac anomalies, and to those with distinct anatomic cardiac subtypes.

M.Cristina Digilio,1 Bruno Marino,2 Bruno Dallapiccola1 1 Medical Genetics, Bambino Gesu' Paediatric Hospital, IRCCS, Rome, Italy; 2 Department of Pediatrics, Pediatric Cardiology, La Sapienza University, Rome, Italy

Correspondence to Dr M.Cristina Digilio, Medical Genetics, Bambino Gesu' Paediatric Hospital, IRCCS, Piazza S.Onofrio 4, 00165 Rome, Italy; mcristina.digilio@opbg.net

REFERENCES 1. van Egelen K, Topf A, Keavney BD, et al. 22q11.2 deletion syndrome is under-recognized in adult patients with tetralogy of Fallot and pulmonary atresia. Heart 2010;96:621-4. 2. Marino B, Digilio MC, Toscano A, et al. Anatomic patterns of conotruncal defects associated with deletion 22q11. Genet Med 2001;3:45-8. 3. Fung WLA, Chow EWC, Webb GD, Gatzoulis MA, Bassett AS. Extracardiac features predicting 22q11.2 deletion syndrome in adult congenital heart disease. Int J Cardiol 2008;131:51-8. 4. Carelle-Calmels N, Saugier-Veber P, Girard-Lemaire F, et al. Genetic Compensation in a Human Genomic Disorder. N Engl J Med 2009;360:1211-6.

Conflict of Interest:

None declared

Remarkably, chest radiography was notable by its absence from the "mandatory fields for completion" in the 2008-2009 national heart failure audit(1) notwithstanding the documentation that clinical markers of congestion have high positive predictive value(PPV) for validation of acute heart failure(2). According to one review, pulmonary vascular redistribution is associated with a PPV of 75% and a negative predictive value(NPV) of 52% for the presence of acute heart failure. Correspondingly, interstitial oedema is associated with PPV and NPV of 78% and 53%, respectively(2). Accordingly the national heart failure audit was a missed opportunity for evaluating the diagnostic accuracy of these two radiographic parameters in the real world References (1) Cleland JG., McDonagh T., Rigby AS et al The national heart failure audit for England and Wales 2008-2009 Heart 2011;97:876-886 (2)Gheorghiade M., Follath F., Ponikowski P et al Assessing and grading congestion in acute heart failure: a scientific statement from the Acute Heart Failure Committee of the Heart Failure Association of the European Society of Cardiology and Endorsed by the European Society of Intensive Care Medicine European Journal of Heart Failure 2010;12:423-33

Conflict of Interest:

None declared