Left ventricular diastolic dysfunction as a predictor of the first diagnosed nonvalvular atrial fibrillation in 840 elderly men and women


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ACC 2009 Advocacy Position Statement: Principles for Comparative Effectiveness Research

2009 ACCF/AHA Focused Update on Perioperative Beta Blockade Incorporated Into the ACC/AHA 2007 Guidelines on Perioperative Cardiovascular Evaluation and Care for Noncardiac Surgery

J Am Coll Cardiol, 2002; 40:1636-1644
© 2002 by the American College of Cardiology Foundation

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CLINICAL STUDY: CLINICAL APPLICATION OF ECHOCARDIOGRAPHIC FINDINGS

Left ventricular diastolic dysfunction as a predictor of the first diagnosed nonvalvular atrial fibrillation in 840 elderly men and women

Teresa S. M. Tsang, MD, FACC^*^,*, Bernard J. Gersh, MB, ChB, DPhil, FACC^*, Christopher P. Appleton, MD, A. Jamil Tajik, MD, FACC^*, Marion E. Barnes, MS^*, Kent R. Bailey, PhD, Jae K. Oh, MD, FACC^*, Cynthia Leibson, PhD, Samantha C. Montgomery, MS and James B. Seward, MD, FACC^*

^* Division of Cardiovascular Diseases, Mayo Clinic, Rochester, Minnesota, USA
Section of Biostatistics, Mayo Clinic, Rochester, Minnesota, USA
Section of Clinical Epidemiology, Mayo Clinic, Rochester, Minnesota, USA
Division of Cardiovascular Diseases, Mayo Clinic, Scottsdale, Arizona, USA

Manuscript received February 20, 2002; revised manuscript received May 15, 2002, accepted July 15, 2002.

^* Reprint requests and correspondence: Dr. Teresa S. M. Tsang, Mayo Clinic, 200 First Street SW, Rochester, Minnesota, USA 55905.
tsang.teresa{at}mayo.edu

Abstract

Top
Abstract
Methods
Results
Discussion
References

OBJECTIVES: The objective of this study was to determine whether diastolicdysfunction is associated with increased risk of nonvalvularatrial fibrillation (NVAF) in older adults with no history ofatrial arrhythmia.

BACKGROUND: Few data exist regarding the relationship between diastolicfunction and NVAF.

METHODS: The clinical and echocardiographic characteristics of patientsage $≥$ 65 years who had an echocardiogram performed between 1990and 1998 were reviewed. Exclusion criteria were history of atrialarrhythmia, stroke, valvular or congenital heart disease, orpacemaker implantation. Patients were followed up in their medicalrecords to the last clinical visit or death for documentationof first AF.

RESULTS: Of 840 patients (39% men; mean [± SD] age, 75 ±7 years), 80 (9.5%) developed NVAF over a mean (± SD)follow-up of 4.1 ± 2.7 years. Abnormal relaxation, pseudonormal,and restrictive left ventricular diastolic filling were associatedwith hazard ratios of 3.33 (95% confidence interval [CI], 1.5to 7.4; p = 0.003), 4.84 (95% CI, 2.05 to 11.4; p < 0.001),and 5.26 (95% CI, 2.3 to 12.03; p < 0.001), respectively,when compared with normal diastolic function. After a numberof adjustments, diastolic function profile remained incrementalto history of congestive heart failure and previous myocardialinfarction for prediction of NVAF. Age-adjusted Kaplan-Meierfive-year risks of NVAF were 1%, 12%, 14%, and 21% for normal,abnormal relaxation, pseudonormal, and restrictive diastolicfilling, respectively.

CONCLUSIONS: The presence and severity of diastolic dysfunction are independentlypredictive of first documented NVAF in the elderly.

Abbreviations and Acronyms
  AF
  atrial fibrillation
  CAD
  coronary artery disease
  CHF
  congestive heart failure
  DT
  deceleration time
  LA
  left atrium or left atrial
  LV
  left ventricle or left ventricular
  MI
  myocardial infarction
  NVAF
  nonvalvular atrial fibrillation

In the face of a burgeoning older population, the prevalenceof atrial fibrillation (AF), which is associated with markedmorbidity, mortality, and socioeconomic burden (1–4),is rapidly increasing. Together with congestive heart failure(CHF) and type 2 diabetes mellitus, AF constitutes one of thethree growing epidemics in the twenty-first century (5,6). Demographically,the decline in rheumatic heart disease in the developed worldhas shifted the etiology toward a preponderance of nonvalvularAF (NVAF) (7), which is one of the most powerful independentrisk factors for stroke (8,9) and is responsible for 75,000strokes annually in the U.S. Although diastolic dysfunction(10) and AF (3) are both age-related conditions, the relationshipbetween diastolic function and the development of NVAF has notbeen defined. The objective of this study was to determine whetherdiastolic dysfunction is associated with increased risk of NVAFin elderly subjects with no prior history of atrial arrhythmias.

Methods

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Abstract
Methods
Results
Discussion
References

Study design and population. A cohort design was used in this study. After the study wasapproved by the Mayo Foundation Institutional Review Board,a list of potential subjects was identified from the computerizedechocardiography database. This list included all residentsof Olmsted County, Minnesota, who underwent at least one transthoracicechocardiogram at Mayo Clinic (Rochester, Minnesota), OlmstedMedical Center (Rochester, Minnesota), or their affiliated hospitalsbetween January 1, 1990, and December 31, 1998, and who wereat least 65 years old on the day of the procedure. Mayo Clinicand its two affiliated hospitals, together with Olmsted MedicalCenter and its affiliated hospital, provide >95% of the medicalcare delivered to Olmsted County residents (11). Consequently,the population from which the sample was drawn included nearlyall elderly Olmsted County residents referred for a transthoracicechocardiogram during the period of interest.

A total of 6,078 Olmsted County residents, age $≥$ 65 years, underwenttransthoracic echocardiography during the period studied. Forpatients who had more than one echocardiogram performed, theearliest examination within the study period was designatedas the baseline study. The list of patients was cross-referencedwith the computerized Mayo Clinic registration file, medicalindex (containing diagnostic codes), surgical database, andelectrocardiographic database. Excluded were 1,772 patientswho, on or before the date of the baseline echocardiogram, hada diagnosis of AF or other atrial arrhythmia, stroke (any type),congenital heart anomaly, or had undergone cardiac valve surgeryor permanent pacemaker implantation. Also excluded were 182patients who denied access to their medical records for researchpurposes. From the remaining 4,124 potential subjects, a randomsample of 2,200 (53%) was drawn by SAS random number selection.Retrospective comprehensive review of the Mayo Clinic medicalrecords of these 2,200 patients was undertaken. During thisreview, an additional 1,360 patients were excluded because theywere found to have exclusion criteria (124 patients), more thanmild valvular disease by echocardiographic criteria (929 patients),or had not (or could not) have assessments of transmitral flowvelocities, left atrial (LA) volume, or body surface area forindexing LA volume (307 patients). The remaining 840 patientsconstituted the study population.

Clinical and echocardiographic data
The medical records of each of the 840 patients were reviewedfor data on age, gender, weight, height, and clinical risk factors.The definition of coronary artery disease (CAD) included a historyof treated angina, a clinical diagnosis of myocardial infarction(MI), any coronary revascularization procedure, or the presenceof $≥$ 50% stenoses in any of the three major coronary arteriesor their larger branches by angiography. Valvular heart diseasewas defined by the presence of more than mild stenosis or regurgitationof any valve. Smoking status was classified as never, past (quitsmoking $≥$ 6 months earlier), or current. Hyperlipidemia was definedby documentation of the diagnosis in the history, current orpast use of a lipid-modifying agent, a fasting total cholesterollevel of $≥$ 200 mg/dl, or a low-density lipoprotein cholesterollevel of $≥$ 130 mg/dl on at least two occasions. Hypertension wasdefined as documentation of the clinical diagnosis and/or useof antihypertensive medications. Diabetes mellitus was definedby the documented clinical diagnosis or treatment with oralhypoglycemic agents or insulin. Family history of CAD referredto the reported presence in first-degree relatives of CAD orangina requiring treatment, MI, coronary artery bypass graftsurgery, or percutaneous transluminal coronary angioplasty.Chronic obstructive pulmonary disease was defined by the clinicaldiagnosis documented in the medical record.

Maximal LA volume was measured offline using the biplane area-lengthmethod (12–14) and also was indexed by body surface area(indexed LA volume). The cardiologists measuring LA volume wereblinded to the outcome of the study, namely, the developmentof NVAF. All other echocardiographic data were retrieved electronicallyfrom the computerized echocardiographic database. These dataincluded M-mode LA dimension, left ventricular (LV) end-systolicand end-diastolic dimensions, LV mass indexed to height, LVejection fraction, LV fractional shortening, LV stroke volume,cardiac index, tricuspid regurgitation velocity, and transmitralflow profile, including peak E velocity, peak A velocity, E/Aratio, and mitral early deceleration time (DT). Unlike othertransmitral flow parameters, isovolumic relaxation time wasnot routinely measured and, therefore, not used for analyses.

The transmitral Doppler flow profile is integral to the assessmentof diastolic function (15). Early transmitral flow begins afterthe pressure in the LV falls below that in the LA and acceleratesto a peak velocity, which is expressed as peak E. As the atrioventricularpressure gradient falls, mitral inflow decelerates, and theduration of the deceleration process is defined by DT. A periodof diastasis follows, during which atrial and ventricular pressuresremain approximately equal. Atrial contraction produces anotherforward pressure gradient, and the peak velocity achieved isexpressed as peak A.

Conventionally, abnormal relaxation is considered the mildestform of diastolic dysfunction (grade I) (15). In our study thepresence of mitral E/A <0.75 or DT >240 ms was consideredevidence of abnormal relaxation. In a more severe stage of diastolicdysfunction with pseudonormal LV filling (grade II), the transmitralflow characteristics are similar to those in patients with normaldiastolic function. However, patients with this abnormalitygenerally have elevated LV filling pressures with an enlargedLA. In this study, both pseudonormal and normal LV filling weredefined by the presence of mitral E/A of 0.75 to 1.50 and DTof 151 to 240 ms, but distinguished by whether LA volume was $≥$ 28 ml/m² (pseudonormal) or <28 ml/m² (normal) (16). Restrictivediastolic filling (grade III, reversibly restrictive; gradeIV, irreversibly restrictive) is associated with markedly elevatedLV filling pressures and is the most severe form of diastolicdysfunction (14,15). In this study the presence of mitral E/A>1.5 or DT $≤$ 150 ms were considered evidence of this abnormality.Due to the retrospective nature of the study, we were not ableto reliably differentiate reversible versus irreversible restrictivephysiology.

Outcome determination
The outcome of interest, namely, first documented NVAF, wasdefined by the first presentation of AF that was clinicallydocumented by a physician. All cases of AF had to be confirmedby electrocardiogram (ECG). The ascertainment of AF was accomplishedthrough review of the medical record of each patient and examinationof the ECGs accompanying the diagnosis. As part of quality assuranceof the medical review, the list of patients with the outcomeevent based on clinical documentation was cross-referenced withmedical index diagnostic code, International Classificationof Diseases 9th revision (ICD-9) 427.31, and with the ECG database.The same ascertainment criteria were applied to all patients.Transient postoperative AF, occurring as an isolated episodewithin one month after surgery, was not counted as an outcomeevent. Because newly documented NVAF, not the duration or persistenceof the arrhythmia, was the outcome event of interest, no distinctionwas made between paroxysmal and persistent NVAF.

Statistical methods
Differences in baseline characteristics between patients whodid and did not develop NVAF after baseline echocardiographywere assessed using chi-square analyses for categorical variablesand rank sum tests for continuous variables. Descriptive statisticsfor both groups were tabulated as means and SD or frequencypercentages.

Simple and multiple Cox proportional hazards analyses were usedto estimate the simple and joint associations among clinicalvariables, echocardiographic variables, and the risk of NVAF.The set of variables was reduced by forward stepwise algorithmuntil only those significant at p < 0.05 remained in themultivariate model. From these models, hazard ratios (HR), 95%confidence intervals (CI), and the associated p values weregenerated.

The age-adjusted effects of indexed LA volume tertiles and diastolicfunction categories on the risk of NVAF were also assessed byan age-stratified weighted Kaplan-Meier and log-rank procedure,with weights reflecting the age stratum proportions in the overallsample (Figs. 1 and 2). To evaluate the incremental prognosticvalue of LA volume and diastolic function profile, the globallog likelihood ratio chi-square statistics for models developedusing: 1) clinical risk factors alone; 2) clinical risk factorsplus log (LA volume); 3) clinical risk factors plus diastolicfunction profile; and 4) clinical risk factors plus diastolicfunction profile and log (LA volume) were determined by Coxproportional hazards regression and depicted graphically (Fig. 3).Because LA volume had a highly skewed distribution, logarithmictransformation was performed, resulting in more normally distributeddata for statistical modeling. In all cases, statistical significancewas defined as two-tailed p < 0.05.

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Figure 1 Age-adjusted cumulative survival without nonvalvular atrial fibrillation (NVAF) by left atrial volume indexed to body surface area (LAVI).

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Figure 2 Age-adjusted cumulative survival without nonvalvular atrial fibrillation (NVAF) by diastolic function profile.

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Figure 3 Predictive power of four models (clinical with only clinical risk factors, clinical and left atrial [LA] volume, clinical and diastolic function profile, and clinical with LA volume and diastolic function profile) for nonvalvular atrial fibrillation.

	Results

Top Abstract Methods Results Discussion References

Baseline characteristics of the study population. A total of 840 residents of Olmsted County, whose mean age was75 ± 7 years (range, 65 to 100 years), met all studycriteria. Of these, 325 (39%) were men with a mean age of 73± 6 years, and 515 were women with a mean age of 76 ±7 years (p < 0.001). The primary indications for echocardiographicassessment were dyspnea (30%), chest discomfort (22%), palpitations,light-headedness, presyncope or syncope (18%), cardiac functionassessment (22%), murmurs (7%), and other reasons (1%). Patientswho developed NVAF after baseline echocardiography were morelikely to have had a history of prior hypertension, MI, CAD,CHF (Table 1), mitral annular calcification, larger LV end-diastolicdimension, greater posterior LV wall thickness, greater LV mass(indexed by height), lower LV ejection fraction, lower LV fractionalshortening, larger LA dimension, and larger LA volume (Table 2).At baseline, 138 patients (16%) were considered to havea normal diastolic function profile, 428 (51%) demonstratedabnormal relaxation, 222 (26%) fulfilled the criteria for pseudonormalLV filling, and 52 (6%; percentages add to <100 due to rounding)had restrictive diastolic physiology. The mean absolute (andindexed) LA volumes for patients with normal, abnormal relaxation,pseudonormal, and restrictive diastolic filling were 41 ±8 ml (22 ± 4 ml/m²), 60 ± 22 ml (33 ± 12ml/m²), 73 ± 20 ml (41 ± 10 ml/m²), and 81 ±38 ml (47 ± 22 ml/m²), respectively.

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Table 1 Baseline Clinical Characteristics of Study Population According to NVAF Status at Follow-Up

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Table 2 Baseline Echocardiographic Characteristics of Study Population According to NVAF Status at Follow-Up^*

Predictors of NVAF
A total of 80 patients (9.5%) developed newly diagnosed, electrocardiographicallyconfirmed, NVAF during a mean follow-up of 4.1 ± 2.7years for the cohort. The average time from echocardiogram toNVAF was 3.0 ± 2.4 years. The significant age- and gender-adjustedpredictors of NVAF are shown in Table 3. In a multivariate clinicalmodel, age, prior history of MI, and history of CHF were independentpredictors of NVAF, while a prior history of hypertension ordiabetes mellitus was not (Table 4). Gender was not a significantpredictor when adjusted for age alone (Table 3), or in any ofthe multivariate models (Table 4).

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Table 3 Predictors of NVAF, Adjusted for Age and Gender

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Table 4 Multivariate Models for Prediction of NVAF

After adjusting for age, larger LA volume was associated withincreased risk of NVAF (Fig. 1). After adjusting for multipleclinical risk factors, LA volume remained incremental to a priorhistory of CHF and MI for the prediction of NVAF (per log: HR,3.51; 95% CI, 1.94 to 6.35; p < 0.001) (Table 4).

The presence and severity of diastolic dysfunction were independentlyassociated with higher risk of NVAF. Abnormal relaxation, pseudonormal,and restrictive diastolic filling were associated with HRs of3.33 (95% CI, 1.50 to 7.40; p = 0.003), 4.84 (95% CI, 2.05 to11.40; p < 0.001), and 5.26 (95% CI, 2.30 to 12.03; p <0.001), respectively, when compared with normal diastolic functionin the same model, unadjusted for other factors. When adjustedfor age and gender (Table 3), and after adjustments for clinicalrisk factors or LA volume (Table 4), diastolic dysfunction remainedindependently predictive of subsequent NVAF. Kaplan-Meier five-yearage-adjusted cumulative risks of NVAF were 1%, 12%, 14%, and21% for patients with normal, abnormal relaxation, pseudonormal,and restrictive LV diastolic filling, respectively (Fig. 2).

Systolic function, measured by ejection fraction as a continuousvariable, was a significant predictor of NVAF when adjustedfor age and gender (Table 3), but not after adjusting for multipleclinical risk factors (Table 4). The predictive power for NVAF,based on global model chi-square value, was improved significantlywith the addition of the diastolic function profile to clinicalrisk factors alone. The predictive value increased further whenLA volume was added to the model. The predictive power of themodel containing only clinical risk factors and LA volume comparedfavorably with that containing clinical risk factors and diastolicfunction profile (Fig. 3).

Discussion

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Abstract
Methods
Results
Discussion
References

Diastolic dysfunction as a predictor of first documented NVAF. This study demonstrated that the presence of diastolic dysfunctionwas associated with increased risk of NVAF in this elderly cohortreferred for echocardiography. Furthermore, the gradient ofrisk appeared to be related to the severity of diastolic dysfunction.A decrease in diastolic performance with advancing age is welldocumented and has been regarded as part of "normative" aging(17,18). Our data challenges the concept that changes in diastolicfunction are "normal for age," as even a mild degree of diastolicdysfunction, such as abnormal relaxation, more than tripledthe likelihood of developing the adverse outcome of AF. Moreover,this occurred over a relatively short follow-up period of approximatelyfour years.

Diastolic dysfunction has also been shown to be largely responsiblefor approximately one-half of all new cases of CHF in the Framinghamstudy (19) and in an Olmsted County study (20). The abilityto detect diastolic abnormalities has been made possible bythe introduction of Doppler echocardiography in the 1980s (21,22),and various sophisticated techniques for increasingly preciseassessment of diastolic function have been developed since then.Simple transmitral flow characteristics, however, remain centralto the evaluation of diastolic function and provide importantprognostic information (23–25). In this study a simplediastolic function profile using only mitral DT, mitral E/A,and LA volume allowed a meaningful stratification of risk forsubsequent NVAF. The diastolic function profile was incrementalto clinical risk factors and LA volume for such prediction (Table 4,Fig. 3).

LA volume as a predictor of NVAF
As in the Framingham Heart study (26) and the CardiovascularHealth study (27), M-mode LA dimension was also found to predictthe development of NVAF in this study. Each 5-mm-larger LA dimensionwas associated with an increase in risk of 48% (Table 3). Leftatrial volume provides a more sensitive assessment of LA enlargement(28), and, as we have shown previously, it is an important independentpredictor of AF, providing incremental information beyond thatafforded by the clinical risk factors and conventional M-modeLA dimension (29). In our previous study, patients with valvularheart disease, a strong determinant of AF, were not excluded.In the current study, LA volume was confirmed to be independentof both clinical risk factors and diastolic function profilefor the prediction of AF in the absence of valvular heart disease(Table 4). The data suggested that the larger the LA volume,the greater the risk of NVAF (Table 3, Fig. 1).

The importance of LA volume as a predictor of NVAF was underscoredby the finding that the predictive value was enhanced furtherby the addition of LA volume to the model that already includedclinical risk factors and the diastolic function profile (Fig. 3).The model based only on clinical risk factors and LA volumecompared favorably with that containing clinical risk factorsand diastolic function profile. These findings lend supportto the contention that LA volume is a robust barometer of diastolicfilling abnormalities (16). While transmitral flow indexes provideimportant information on diastolic function, they are knownto be load-dependent (21). Although speculative at this point,it is possible that the relationship between transmitral inflowcharacteristics and LA volume may be analogous to that betweenserum glucose and glycosylated hemoglobin. Left atrial volumemay provide a measure of chronicity, and not just severity ofdiastolic dysfunction, and the chronicity may, in turn, reflectthe extent of alterations in the atrial substrate predisposingto electrophysiologic abnormalities and development of arrhythmia.

Clinical risk factors for predicting NVAF
The incidence of NVAF in this referral study population was23.2 per 1,000 person-years. This was, as expected, higher thanthat identified in the Cardiovascular Health study of randomlyselected community members who were 65 years or older and fulfilledMedicare eligibility (19.2 per 1,000 person-years) (27). Inboth studies there was a predominance of women (Olmsted referralstudy, 61%; Cardiovascular Health study, 57%). Like other investigators(26,27), we found certain clinical variables to be importantpredictors of NVAF (Tables 3 and 4). However, in contrast, wefound that hypertension was not independently significant afteradjusting for multiple factors. That hypertension did not retainindependent significance could reflect the high prevalence ofthe condition in this cohort at baseline. In addition, unlikesome studies, male gender was not an independent predictor.The reason for this finding is uncertain, although our cohortdid include a greater proportion of women than some other populationsthat have been studied. Our study, however, demonstrated thatthe inclusion of LA volume and the diastolic function profilesignificantly augmented the predictive value of models basedon clinical risk factors alone (Fig. 3).

Mechanism for diastolic dysfunction as a precursor for the development of NVAF
In this study of older adults, even a milder form of diastolicdysfunction, namely, abnormal relaxation, appeared to increasethe propensity for NVAF, independent of the effects of age.Skubas et al. (30) reported that diastolic relaxation abnormalitieswere highly prevalent in patients presenting for the Maze procedure.It is conceivable that LV relaxation abnormalities lead to areduction in passive LA emptying, with the development of higheratrial pressures during atrial diastole. This, in turn, mayresult in a larger LA volume at the onset of atrial systole,with enhanced atrial ejection occurring as a compensatory response(31). Over time, the LA and pulmonary veins dilate. The distentionand stretching of these structures may potentiate electricalremodeling, with shortening of the atrial effective refractoryperiod (32) or an increase in dispersion of refractoriness,resulting in vulnerability to AF (33,34).

Both passive atrial stretch and an increase in atrial pressureduring atrial contraction have been found to stimulate the releaseof atrial natriuretic factor (35). In addition, Grandi et al.(36) demonstrated that diastolic impairment is the main influenceon the levels of atrial natriuretic factor in patients withmild hypertension. In one study the level of atrial natriureticfactor was found to be a predictor of paroxysmal AF (37). Thus,the relationship between diastolic abnormalities and the developmentof NVAF may be mediated through an increase in atrial pressure,atrial stretch, and neurohormonal activation, including therelease of atrial natriuretic factor.

Study limitations
The clinical data for this study were obtained by retrospectivechart review; therefore, certain inherent biases are possible.The method of ascertainment of AF, based on clinical documentationwith electrocardiographic confirmation, could have underestimatedthe actual number of incident AF cases. For instance, some patientswith AF could have been asymptomatic, and if they did not presentto the medical system for other reasons, the arrhythmia couldhave remained undetected for some time. However, it was previouslyestablished that 96% of Olmsted County residents aged 65 to74 years had at least one encounter with the Mayo medical systemwithin a three-year period (11). For simplicity, we used mitralinflow characteristics and LA volume in the construction ofa diastolic function profile for prediction of the outcome eventof NVAF. It is recognized that more refined discrimination ofcategories of diastolic dysfunction can be achieved if additionalassessments, including pulmonary venous flow, color M-mode,and tissue Doppler imaging techniques, are also used. However,given the study period being 1990 to 1998, pulmonary venousflow measurements were not available in a considerable numberof studies during the earlier half of the period, and tissueDoppler assessments did not become part of routine standardechocardiogram study until 1999. Color M-mode was used onlyselectively during this period of time. Because all subjectswere patients referred for echocardiographic assessment at MayoClinic or Olmsted Medical Center, the extent to which the findingscan be generalized to the rest of Olmsted County residents andto non-Olmsted residents is unknown. The population studiedwas predominantly white, and whether similar findings can beidentified in other racial groups needs to be verified in futurestudies.

Conclusions
Diastolic dysfunction appears to be a potent precursor of NVAFin the elderly, with an independent, graded relationship betweenthe severity of diastolic dysfunction and the development ofNVAF. These findings provide a foundation for further investigationinto the links between age, diseased atrial substrate, electrophysiologicremodeling, and subsequent AF, as well as a compelling rationalefor search of effective approaches to prevent and reverse diastolicdysfunction, which may have far-reaching public health consequences.

Footnotes

Grant support provided by the American Heart Association andthe American Society of Echocardiography.

References

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Discussion
References

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