Serial clinical and echocardiographic evaluation in children with Marfan syndrome

Lopez, Victor Manuel Oporto; Perez, Ana Beatriz Alvarez; Moisés, Valdir Ambrósio; Gomes, Lourdes; Pedreira, Patricia da Silveira; Silva, Célia C.; Campos Filho, Orlando; Carvalho, Antônio Carlos C.

doi:10.1590/S0066-782X2005001800003

Abstracts

OBJECTIVE: To describe the clinical cardiac manifestations and temporal evolution of Marfan syndrome in children; to estimate the incidence of annuloaortic ectasia and mitral valve prolapse; and to evaluate tolerability and efficacy of beta-blockers in these patients. METHODS: During one year, 21children with Marfan syndrome underwent serial clinical and echocardiographic examinations. Echocardiograms assessed: the presence of mitral valve prolapse, aortic root diameter, mitral and aortic valves regurgitation, and aortic enlargement during beta-blocker therapy. Eleven patients had two measurements of the aortic root taken one year apart. RESULTS: The children were asymptomatic throughout the study. Mitral prolapse was found in 11 (52%) children. Annuloaortic ectasia occurred in 16 (76%) patients and found to be mild in 42.8%, moderate in 9.5%, and severe in 23.8%. One of these patients underwent aortic valve replacement and repair of the ascending aorta by the Bentall-De Bono technique, with good results. Heart rate decreased by 13.6% (from 85 to 73 bpm; p < 0.009) with the use of beta-blockers; however, aortic root diameter increased by 1.4 mm/year (p<0.02). One child could not be given beta-blockers due to bronchial asthma, and no significant side effects were observed in the remaining children, including one who also had bronchial asthma. CONCLUSION: The children remained asymptomatic throughout the study, the use of beta-blockers led to a significant decrease in heart rate, and no significant adverse effects were observed. Contrary to the literature, incidence of annuloaortic ectasia was high among the study population, greater than that of mitral valve prolapse, even during beta-blocker therapy.

Marfan syndrome; thoracic aortic aneurysm; mitral valve prolapse; Doppler echocardiography

OBJETIVO: Descrever a apresentação clínica cardiológica e a evolução temporal, estimar a incidência de ectasia ânulo-aórtica e de prolapso da valva mitral, e avaliar a tolerância e a efetividade dos betabloqueadores em crianças com síndrome de Marfan. MÉTODOS: Foram submetidas a exame clínico e ecocardiográfico seriado, durante um ano, 21 crianças com síndrome de Marfan. No ecocardiograma foram analisados: presença de prolapso mitral, diâmetro da raiz aórtica, refluxos das valvas mitral e aórtica, e o crescimento dos diâmetros aórticos na vigência de betabloqueadores. Em 11 pacientes foi possível obter duas medidas da raiz aórtica no intervalo de um ano. RESULTADOS: Durante o estudo as crianças não apresentaram sintomas. Prolapso mitral foi encontrado em 11 (52%) crianças. Ectasia ânulo-aórtica ocorreu em 16 (76%) pacientes, sendo de grau discreto em 42,8%, moderado em 9,5%, e importante em 23,8%. Um desses pacientes foi submetido com sucesso à cirurgia de Bentall DeBono. Com o uso de betabloqueador a freqüência cardíaca diminuiu 13,6% (de 85 para 73 bpm; p < 0,009), mas houve um crescimento da raiz aórtica de 1,4 mm/ano (p < 0,02). Uma criança não pôde receber betabloqueador em razão de asma brônquica, e não foram observados efeitos colaterais significativos nas outras crianças, incluindo uma com asma brônquica. CONCLUSÃO: Os resultados obtidos sugerem que, no período observado, as crianças permaneceram assintomáticas, o uso de betabloqueadores diminuiu significativamente a freqüência cardíaca e não se acompanhou de efeitos adversos significativos. Ao contrário da literatura, a incidência de ectasia ânulo-aórtica foi elevada e maior do que a de prolapso valvar mitral, tendo crescimento mesmo na vigência de uso eficaz de betabloqueador.

síndrome de Marfan; aneurisma de aorta torácica; prolapso da valva mitral; ecocardiografia com Doppler

ORIGINAL ARTICLE

Serial clinical and echocardiographic evaluation in children with Marfan Syndrome

Victor Manuel Oporto Lopez; Ana Beatriz Alvarez Perez; Valdir Ambrósio Moisés; Lourdes Gomes; Patricia da Silveira Pedreira; Célia C. Silva; Orlando Campos Filho; Antônio Carlos C. Carvalho

Universidade Federal de São Paulo - UNIFESP - São Paulo, SP - Brazil

^{Mailing address} Mailing address Victor Manuel Oporto Lopez R: Ouvidor Peleja, 779 04128-001 - São Paulo, SP - Brazil E-mail: victoroporto666@hotmail.com

ABSTRACT

OBJECTIVE: To describe the clinical cardiac manifestations and temporal evolution of Marfan syndrome in children; to estimate the incidence of annuloaortic ectasia and mitral valve prolapse; and to evaluate tolerability and efficacy of beta-blockers in these patients.

METHODS: During one year, 21 children with Marfan syndrome underwent serial clinical and echocardiographic examinations. Echocardiograms assessed: the presence of mitral valve prolapse, aortic root diameter, mitral and aortic valves regurgitation, and aortic enlargement during beta-blocker therapy. Eleven patients had two measurements of the aortic root taken one year apart.

RESULTS: The children were asymptomatic throughout the study. Mitral prolapse was found in 11 (52%) children. Annuloaortic ectasia occurred in 16 (76%) patients and found to be mild in 42.8%, moderate in 9.5%, and severe in 23.8%. One of these patients underwent aortic valve replacement and repair of the ascending aorta by the Bentall-De Bono technique, with good results. Heart rate decreased by 13.6% (from 85 to 73 bpm; p < 0.009) with the use of beta-blockers; however, aortic root diameter increased by 1.4 mm/year (p<0.02). One child could not be given beta-blockers due to bronchial asthma, and no significant side effects were observed in the remaining children, including one who also had bronchial asthma.

CONCLUSION: The children remained asymptomatic throughout the study, the use of beta-blockers led to a significant decrease in heart rate, and no significant adverse effects were observed. Contrary to the literature, incidence of annuloaortic ectasia was high among the study population, greater than that of mitral valve prolapse, even during beta-blocker therapy.

Keywords: Marfan syndrome, thoracic aortic aneurysm; mitral valve prolapse; Doppler echocardiography

The Marfan syndrome is named after Antoine Marfan, a French pediatrician who in 1896 presented the case of a 5-year-old girl to the Societé Médicale des Hôpitaux in Paris¹. Clinical characteristics and natural history of the disease were described for the first time, in an ordered manner, by McKusick in 1955². Marfan syndrome is an inherited autosomal dominant disorder of the connective tissue, with variable expression, which affects primarily the skeletal, ocular and cardiovascular systems. Its prevalence is estimated at about 1/10,000 individuals. However, other estimates suggest higher figures ranging from 4 to 6/10,000 individuals³. Marfan syndrome results from mutations in the fibrillin 1 gene (FBN1)⁴. The primary cardiovascular changes are annuloaortic ectasia and mitral valve prolapse. Owing to these changes, life expectancy of patients with Marfan syndrome just a few years ago was up to the third or forth decade of life⁵, but a greater knowledge of the disease and the advent of surgical techniques in the last years led to a significant improvement in prognosis⁶.

Most papers published in the literature describe adult patients^2-7,8; however, pediatric population is not free from complications. Therefore, the aim of the present study is threefold: to describe the clinical cardiac manifestations and temporal evolution of Marfan syndrome in children; to estimate the incidence of annuloaortic ectasia and mitral valve prolapse; and to evaluate tolerability and efficacy of beta-blockers in these patients.

METHODS

Between January 1999 and November 2000, 21 children with Marfan syndrome - 13 (62%) boys and 8 (38%) girls - were prospectively evaluated. Using the reviewed criteria, the syndrome was confirmed in all the patients⁹. Ages ranged from nine months to sixteenth years (median 10 years). Patients' body weight ranged from 8 to 70 kg. The study protocol was approved by the Institutional Research Ethics Committee, and written informed consent was obtained from all legal guardians of the children for their inclusion in the study.

The same examiner performed all serial clinical and echocardiographic examinations. A chest radiograph was taken on the first visit and an electrocardiogram on each follow-up visit. All patients were maintained on beta-blocker medication, except those with any contraindication; younger children received propranolol, and the others received atenolol. Systemic blood pressure could not be obtained in all children, and dosage of beta-blocker was based solely on heart rate, that is to say, the necessary dosage to maintain heart rate at around 60 bpm or the maximum dosage of the drug for body weight. All school-age children were instructed not to engage in competitive physical activities.

Echocardiograms were performed using ATL HDI 1500, ATL 5000, or Phillips SD-800 machines equipped with a 2.5 or 5 MHz electronic, multifrequency transducers. Heart cavities and aortic root measurements (in the Valsalva sinuses area) were performed by two-dimensional guided M-mode echocardiographs; only one patient had aortic root measurement taken in two-dimensional mode using the parasternal long-axis view at end-diastole.

Mitral valve prolapse was defined by echocardiographic examination using Freed et al' criteria¹⁰ (superior displacement of one or both mitral leaflets by more than 2 mm above the mitral annular plane during ventricular systole on the parasternal long-axis view).

Mitral and aortic valve regurgitation was further divided into two groups: mild or minor and significant (moderate and severe) After gain adjustment and maximum increase of Nyquist velocity, reflux severity was assessed visually and subjectively, taking into account morphological changes of mitral valve, cavities measurements and regurgitant jet into the left atrium¹¹. Later, interobserver analysis for the quantification of mitral regurgitation was performed. Two experienced and independent examiners reviewed images of ten examinations recorded on VHS tape and, using the same method, determined the degree of valve regurgitation.

Aortic regurgitation was estimated by the ratio of jet width to the left ventricular outflow tract on color flow mapping¹¹.

Annuloaortic ectasia grading was based on reference values used by the Echocardiography Department (adapted from Roge et al)¹² and was established by weight range following the criterion below: a) up to 20%, mild enlargement; b) between 20 and 40%, moderate enlargement; c) above 40%, major enlargement.

Both measurements were performed using the paired Student's t-test for correlated samples, in this case, comparison of aortic root enlargement and heart rate behavior during beta-block administration after one year, where p < 0.05 was considered significant. Interobserver variability of mitral regurgitation was assessed by Kappa test.

RESULTS

All children remained asymptomatic during the one-year follow-up, with no evidence of heart failure, including the few with significant valve regurgitation. No asymmetries were found on peripheral pulse palpation. A two-year-old child underwent replacement of the ascending aorta by the Bentall-De Bono technique, due to severe annuloaortic ectasia with rapid enlargement of the ascending aorta and worsening of aortic regurgitation.

Annuloaortic ectasia occurred in 16 (76%) patients and found to be mild in 42.8%, moderate in 9.5%, and severe in 23.8% (five children) (fig 1). Eleven (52%) children had two measurements of the aortic root taken one year apart. Mean annual increase of aortic diameter was 10%, meaning 1.4 mm/year (p < 0.02) (tab I). Only three children (14.2%) had aortic valve regurgitation, with a mild regurgitation at the initial evaluation; however, in one child the regurgitation evolved to a moderate-to-severe degree.

Thumbnail

Mitral valve heart murmur was heard in six (28.6%) children, three of which were considered intense. Mitral click was heard in 13 (61%) patients. On echocardiographic examination, 11 (52%) patients had valve prolapse and 3 (14%) patients had significant mitral regurgitation, one of which was deemed severe and the other two moderate. In the interobserver analysis performed later for assessment of mitral regurgitation, a Kappa value of 0.635 was calculated, and as can be seen in the corresponding table (table II), most differences occurred in trivial regurgitation.

Thumbnail

Beta-blocker therapy was attempted in all patients, including two children with history of bronchial asthma; this was tolerated by only one of them. Discontinuation of therapy would be made only if necessary, such as in case of bronchospasm. After beta-blocker therapy was introduced, a decrease in mean hear rate was observed, from 85 bpm to 73 bpm (p < 0.009) (table I).

DISCUSSION

Marfan syndrome is a hereditary disease caused by a mutation in the gene for fibrillin located on chromosome 15. In 1972, Murdoch et al⁵ demonstrated the early mortality of patients with Marfan syndrome between the third and fourth decade of life. Moreover, the number of deaths of patients under twenty years of age was not at all negligible (25% of the total number of deaths of the studied population). Cardiovascular death occurred in 93% of patients, most often secondary to aortic rupture, dissection or insufficiency. Later, other studies showed a significant improvement in survival afforded by advances in diagnosis, clinical treatment and, especially, surgical techniques.⁶ Recently, Gott et al¹³, emphasized the importance of elective surgery for annuloaortic ectasia, with low operative mortality rates. Conversely, emergency surgery was associated with a much higher mortality rate.

Although all patients of our series have remained asymptomatic, a two-year-old child with neonatal Marfan syndrome, the most severe form of the disease, required replacement of the ascending aorta with a valved tube (Bentall-De Bono technique)¹⁴. This child had already presented for initial evaluation with a 26-mm aortic root (the upper limit of normal for the child's body weight should be 17 mm) and mild aortic regurgitation. In a single year the aortic root diameter increased 5 mm (19%), reaching 31 mm, followed by a worsening of aortic regurgitation. Albeit asymptomatic, the child required surgical correction, due to the impending risk of aortic rupture or dissection. Currently, the child is in general good condition and taking acetylsalicylic acid as the anti-platelet agent, because of the mechanical aortic prosthesis.

Four other children with severe annuloaortic ectasia are waiting for surgery. One of them required a concomitant mitral valve repair for significant mitral regurgitation.

Earlier studies showed an incidence of mitral valve prolapse of up to 100%^15-16, yet rates are around 70% in most publications¹⁷. In the present study, the incidence of mitral prolapse was 52.4% (11 patients). This may be partly explained by the stricter criteria used in our protocol. Significant mitral regurgitation was detected in only 3 (14%) patients, and a single one was severe. The incidence of annuloaortic ectasia was 76% (16 patients), of which 23% was severe and, therefore, potentially more serious. While mitral regurgitation is usually progressive, annuloaortic ectasia, despite also increasing over time, can complicate abruptly once a significant degree of dilation is reached, leading to catastrophic outcomes, such as dissection or rupture. Eleven (52%) children had two measurements of the aortic root taken one year apart. Mean annual increase of aortic diameter was 10%, or 1.36 mm/year (p value p < 0.02).

In the study by Shores et al,¹⁸ which included adults and adolescents, the ratio of aortic enlargement (measured diameter divided by expected diameter) was 0.023 in the treated group versus 0.084 in the control group. The study showed an increase of 2.1 ±1.6 mm/year in the non-treated group versus 0.7±1.8 mm/year and 1.1±1.1 mm/year in two groups of patients treated with atenolol or propanolol, all of them with p < 0.05¹⁹.

The faster rate of aortic root enlargement in our group may be partly explained by the age range of the population studied, since relative aortic root enlargement is higher during childhood and adolescence than in adulthood, and partly because, in our group, a child with the neonatal form of Marfan syndrome accounted, alone, for a 5-mm enlargement, representing 19% of the initial diameter.

Echocardiographic image of annuloaortic ectasia is typical of Marfan syndrome ("pear-shaped"), with a greater degree of dilation at the Valsalva sinuses and extending to the sinotubular junction). Progressive dilation can compromise the remainder of the ascending and the aortic arch. Aortic root dilation also predispose both to a failure of central coaptation and aortic valve regurgitation²⁰.

Although other authors also have reported changes in the ascending aorta as the most serious lesions of Marfan syndrome in children^7-21-24, many textbooks on cardiology still suggest that mitral valve lesions are the most important in this pediatric group²⁵, to some degree because the research material included data of the time in which the echocardiogram was not available²⁶ as a routine method to assess the aortic root. It is known that plain chest radiograph alone does not allow a complete evaluation of that portion of the aorta²⁷. Several studies pointing toward the mitral valve as the primary cause of morbidity and mortality in the pediatric group were conducted in children with the more severe, neonatal form of the disease²⁸, in which mitral valve prolapse with severe regurgitation and intractable heart failure is more frequent²⁹.

The beta-blocker used was atenolol, due to its easy dosage regimen. Only a one-year-old child with a history of bronchial asthma was given propranolol initially. The bradycardiac response was both variable and unpredictable. Some patients responded satisfactorily with a heart rate around 60 bpm, whereas others, including those on maximum dosage, got only modest results. An asthmatic child tolerated beta-blocker therapy, with discontinuation of medication only during bronchospasm episodes. Even so, there was a decrease in average resting heart rate, which dropped from 84 bpm to 73 bpm (p < 0.009); minimum heart rate also dropped from 55 bpm to 48 bpm, and maximum heart went from 155 bpm to 115 bpm.

Some limitations of the study should be noted, such as the relatively small number of patients included in the sample and of those in whom two evaluations could be made at a one-year interval, time that could be considered too short; however, as children usually grow fast, the variations observed may reflect the actual progressive involvement of the aortic root in children with Marfan syndrome. The mean enlargement of aortic root of 1.4 mm/year, though statistically significant to the group, should be considered carefully, because variations about 1 mm may be observed in daily practice, with no clinical significance. Nevertheless, it should be emphasized that, at study conclusion, 76% of the patients had annuloaortic ectasia, reference value for body weight considered.

Regardless of the limitations mentioned, the children remained asymptomatic throughout the study, the use of beta-blockers led to a significant reduction in heart rate, and no significant adverse effects were observed. Contrary to the literature, the incidence of annuloaortic ectasia was high (72%), greater than that of mitral valve prolapse (52.4%), and an enlargement of 1.4 mm/year was observed even during the effective use of beta-blockers.

REFERENCES

Received on 11/05/03

Accepted on 04/29/05

1. Marfan AB. Un cas de déformation congénitale des quatre membres, plus prononcée aux extrémités, caractérisée par l'allongement des avec un certain degré d'amincissement. Bull - Mem Soc Med Hop - Paris 1896;13:220-6.
2. McKusick VA. The cardiovascular aspects of Marfan's syndrome: a heritable disorder of connective tissue. Circulation 1955;XI:321-42.
3. Pyeritz RE, McKussick VA. The Marfan Syndrome: diagnoses and management. N Engl J Med 1979;300:772-7.
4. Pereira L, D'Alessio M, Ramirez F et al. Genomic organization of the sequence coding for fibrillin, the defective gene product in Marfan syndrome. Hum Molec Genet 1993;2:961-8.
5. Murdoch JL, Walker BA, Halpern BL, Kuzma JW, McKussick VA. Life expectancy and causes of death in the Marfan syndrome. N Engl J Med 1972;286:804-8.
6. Silverman DI, Burton KJ, Gray J et al. Life expectancy in the Marfan syndrome. Am J Cardiol 1995;75:157-60.
7. Marsalese DL, Moodie DS, Vacante M et al. Marfan's syndrome: natural history and long term follow-up of cardiovascular involvement. J Am Coll Cardiol 1989;14:422-8.
8. Fernandes F, Ninoyima OH, Kawano C, Ramires FJ. Análise retrospectiva de 49 pacientes de síndrome de Marfan. Rev Bras Cardiol 2000;2:80-3.
9. De Paepe A, Devereaux RB, Dietz HC, Hennekam RC, Pyeritz RE. Revised diagnostic criteria for the Marfan Syndrome. Am J Med Genet 1996;62:417-26.
10. Freed LA, Levy D, Levine RA et al. Prevalence and clinical outcome of mitral valve prolapse. N Engl J Med 1999;341:1-7.
11. Zoghbi WA, Enriquez-Sarano M, Foster E et al. American Society of Echocardiography report. Recommendations for evaluation of the severity of native valvular regurgitation with two-dimensional and Doppler echocardiography. JASE 2003;16:777-802.
12. Roge CL, Silverman NH, Hart PA, Ray RM. Cardiac structure growth pattern determined by echocardiography. Circulation 1978;57:285-90.
13. Gott VL, Greene PS, Alejo DE et al. Replacement of the aortic root in patients with Marfan's syndrome. N Engl J Med 1999;340:1307-13.
14. Bentall H, De Bono A. A technique for complete replacement of the ascending aorta. Thorax 1968;23:338-9.
15. Brown OR, DeMots H, Kloster FE, Roberts A, Menashe VD, Beals RK. Aortic root dilatation and mitral valve prolapse in Marfan's syndrome. Circulation 1975;52:651-7.
16. Geva T, Hegesh J, Frand M. The clinical course and echocardiographic features of Marfan's syndrome in childhood. AJDC 1987;141:1179-82.
17. Pyeritz RE, Wappel MA. Mitral valve dysfunction in the Marfan syndrome: Clinical and echocardiographic study of prevalence and natural history. Am J Med 1983;74:797-807.
18. Shores J, Berger KR, Murphy EA, Pyeritz RE. Progression of aortic dilatation and the benefit of long term (beta)-adrenergic blockade in Marfan's syndrome. N Engl J Med 1994;330:1335-41.
19. Salim MA, Alpert BS, Ward JC, Pyeritz RE. Effect of beta-adrenergic blockade on aortic root rate of dilation in the Marfan syndrome. Am J Cardiol 1994;74:629-33.
20. Roberts WC, Honig MD. The spectrum of cardiovascular disease in the Marfan syndrome: a clinic-morphologic study of 18 necropsy patients and comparison to 151 previously reported necropsy patients. Am Heart J 1982;104:115-35.
21. Caves PK, Paneth M. Replacement of the mitral valve, aortic valve, and ascending aorta with coronary transplantation in a child with the Marfan syndrome. Thorax 1972;27:58-65.
22. Patton DJ, Galliani CA, Johnson WH, Hedlund GL. Sudden death in Marfan syndrome. AJR 1995;165:160-1.
23. El Habbal MH. Cardiovascular manifestations of Marfan's syndrome in the young. Am Heart J 1992;123:752-7.
24. Gillinov AM, Zher KJ, Redmond JM et al. Cardiac operations in children with Marfan's syndrome: indications and results. Ann Thorac Surg 1997;64:1140-5.
25. Braunwald E. A Textbook of Cardiovascular Medicine. 5th ed. Philadelphia: WB Saunders Company, 1997.
26. Phornphutkul C, Rosenthal A, Nadas A. Cardiac manifestations of Marfan syndrome in infancy and childhood. Circulation 1973;XLVII:587-96.
27. Viamonte Jr. M, Camacho M, Cahill D, Viamonte M, Mori K. The Deceptive aortic root. Circulation 1975;51:389-93
28. Morse RP, Rockenmacher S, Pyeritz RE, Sanders SP, Bieber FR, Lin A, et al. Diagnosis and management of infantile Marfan syndrome. Pediatrics 1990;86:888-95.
29. Amaral FT, Carvalho SR, Granzotti JA, Vieira LH, Pina Neto JM, Nunes MA. Insuficiência cardíaca neonatal e síndrome de Marfan. Arq Bras Cardiol 1996;67:355-7.

Mailing address

Victor Manuel Oporto Lopez

R: Ouvidor Peleja, 779

04128-001 - São Paulo, SP - Brazil

E-mail:

victoroporto666@hotmail.com

Publication Dates

Publication in this collection
05 Dec 2005
Date of issue
Nov 2005

History

Received
05 Nov 2003
Accepted
29 Apr 2005

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

[1] 1. Marfan AB. Un cas de déformation congénitale des quatre membres, plus prononcée aux extrémités, caractérisée par l'allongement des avec un certain degré d'amincissement. Bull - Mem Soc Med Hop - Paris 1896;13:220-6.

[2] 2. McKusick VA. The cardiovascular aspects of Marfan's syndrome: a heritable disorder of connective tissue. Circulation 1955;XI:321-42.

[3] 3. Pyeritz RE, McKussick VA. The Marfan Syndrome: diagnoses and management. N Engl J Med 1979;300:772-7.

[4] 4. Pereira L, D'Alessio M, Ramirez F et al. Genomic organization of the sequence coding for fibrillin, the defective gene product in Marfan syndrome. Hum Molec Genet 1993;2:961-8.

[5] 5. Murdoch JL, Walker BA, Halpern BL, Kuzma JW, McKussick VA. Life expectancy and causes of death in the Marfan syndrome. N Engl J Med 1972;286:804-8.

[6] 6. Silverman DI, Burton KJ, Gray J et al. Life expectancy in the Marfan syndrome. Am J Cardiol 1995;75:157-60.

[7] 7. Marsalese DL, Moodie DS, Vacante M et al. Marfan's syndrome: natural history and long term follow-up of cardiovascular involvement. J Am Coll Cardiol 1989;14:422-8.

[8] 8. Fernandes F, Ninoyima OH, Kawano C, Ramires FJ. Análise retrospectiva de 49 pacientes de síndrome de Marfan. Rev Bras Cardiol 2000;2:80-3.

[9] 9. De Paepe A, Devereaux RB, Dietz HC, Hennekam RC, Pyeritz RE. Revised diagnostic criteria for the Marfan Syndrome. Am J Med Genet 1996;62:417-26.

[10] 10. Freed LA, Levy D, Levine RA et al. Prevalence and clinical outcome of mitral valve prolapse. N Engl J Med 1999;341:1-7.

[11] 11. Zoghbi WA, Enriquez-Sarano M, Foster E et al. American Society of Echocardiography report. Recommendations for evaluation of the severity of native valvular regurgitation with two-dimensional and Doppler echocardiography. JASE 2003;16:777-802.

[12] 12. Roge CL, Silverman NH, Hart PA, Ray RM. Cardiac structure growth pattern determined by echocardiography. Circulation 1978;57:285-90.

[13] 13. Gott VL, Greene PS, Alejo DE et al. Replacement of the aortic root in patients with Marfan's syndrome. N Engl J Med 1999;340:1307-13.

[14] 14. Bentall H, De Bono A. A technique for complete replacement of the ascending aorta. Thorax 1968;23:338-9.

[15] 15. Brown OR, DeMots H, Kloster FE, Roberts A, Menashe VD, Beals RK. Aortic root dilatation and mitral valve prolapse in Marfan's syndrome. Circulation 1975;52:651-7.

[16] 16. Geva T, Hegesh J, Frand M. The clinical course and echocardiographic features of Marfan's syndrome in childhood. AJDC 1987;141:1179-82.

[17] 17. Pyeritz RE, Wappel MA. Mitral valve dysfunction in the Marfan syndrome: Clinical and echocardiographic study of prevalence and natural history. Am J Med 1983;74:797-807.

[18] 18. Shores J, Berger KR, Murphy EA, Pyeritz RE. Progression of aortic dilatation and the benefit of long term (beta)-adrenergic blockade in Marfan's syndrome. N Engl J Med 1994;330:1335-41.

[19] 19. Salim MA, Alpert BS, Ward JC, Pyeritz RE. Effect of beta-adrenergic blockade on aortic root rate of dilation in the Marfan syndrome. Am J Cardiol 1994;74:629-33.

[20] 20. Roberts WC, Honig MD. The spectrum of cardiovascular disease in the Marfan syndrome: a clinic-morphologic study of 18 necropsy patients and comparison to 151 previously reported necropsy patients. Am Heart J 1982;104:115-35.

[21] 21. Caves PK, Paneth M. Replacement of the mitral valve, aortic valve, and ascending aorta with coronary transplantation in a child with the Marfan syndrome. Thorax 1972;27:58-65.

[22] 22. Patton DJ, Galliani CA, Johnson WH, Hedlund GL. Sudden death in Marfan syndrome. AJR 1995;165:160-1.

[23] 23. El Habbal MH. Cardiovascular manifestations of Marfan's syndrome in the young. Am Heart J 1992;123:752-7.

[24] 24. Gillinov AM, Zher KJ, Redmond JM et al. Cardiac operations in children with Marfan's syndrome: indications and results. Ann Thorac Surg 1997;64:1140-5.

[25] 25. Braunwald E. A Textbook of Cardiovascular Medicine. 5th ed. Philadelphia: WB Saunders Company, 1997.

[26] 26. Phornphutkul C, Rosenthal A, Nadas A. Cardiac manifestations of Marfan syndrome in infancy and childhood. Circulation 1973;XLVII:587-96.

[27] 27. Viamonte Jr. M, Camacho M, Cahill D, Viamonte M, Mori K. The Deceptive aortic root. Circulation 1975;51:389-93

[28] 28. Morse RP, Rockenmacher S, Pyeritz RE, Sanders SP, Bieber FR, Lin A, et al. Diagnosis and management of infantile Marfan syndrome. Pediatrics 1990;86:888-95.

[29] 29. Amaral FT, Carvalho SR, Granzotti JA, Vieira LH, Pina Neto JM, Nunes MA. Insuficiência cardíaca neonatal e síndrome de Marfan. Arq Bras Cardiol 1996;67:355-7.

Brasil