Low-frequency renal sympathetic nerve activity, arterial BP, stationary "1/f noise," and the baroreflex

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Low-frequency renal sympathetic nerve activity, arterial BP, stationary "1/f noise," and the baroreflex

Don E. Burgess¹^,², Tabitha A. Zimmerman¹, Marshall T. Wise¹, Sheng-Gang Li², David C. Randall²^,³, and David R. Brown³

¹ Department of Chemistry and Physics, Asbury College, Wilmore 40390-1198; ² Department of Physiology, University of Kentucky College of Medicine, Lexington 40536-0084; and ³ Center for Biomedical Engineering, University of Kentucky, Lexington, Kentucky 40506-0070

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The object of this study is to quantify the very low frequency (i.e., <0.1 Hz) interactions between renal sympathetic nerveactivity (SNA) and arterial blood pressure (ABP). Six rats wereinstrumented for chronic recordings of SNA and ABP. Data werecollected 24 h after surgery at 10 kHz for 2-5 h and subsequentlycompressed to a 1-kHz signal. The power spectra and ordinary coherencewere calculated from data epochs up to 1 h in length. The verylow frequency spectra for both variables were fitted to a constanttimes f . The peak magnitude squared of the coherence near 0.4 Hz was0.82 ± 0.08, but the apparent linear coherence fell off quicklyat lower frequencies so that it was close to zero for frequencies<0.1 Hz. Moreover, at these low frequencies $beta$ , as computed bya coarse grain spectral analysis, was significantly (P < 0.01)different for SNA (0.66 ± 0.12) and ABP (1.12 ± 0.14). Assumingthat SNA and ABP are stationary time series, the results of ourclassical spectral analysis would indicate that SNA and ABP arenot linearly correlated at frequencies with a period more than~10 s. Accordingly, we tested for stationarity by computing thespectral coherence and found that SNA and ABP are not stationary"1/f noise" within the frequency range from 0.02 to 2.0 Hz. Ratherthe SNA exerts control over the cardiovascular system throughintermittent bursts of activity. Such intermittent behavior canbe modeled by nonlineardynamics.

coherence; spectral coherence; nonlinearity; blood pressure

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

THERE IS INCREASING RECOGNITION that the application of the tools of signal processing to biological signals can teach usa great deal about the organization and operation of biologicalcontrol systems. The regulation of arterial blood pressure (ABP)is of particular interest in this regard because blood pressureis subject to a number of different physiological control mechanisms.For example, there is a great deal of evidence that neural mechanismsparticipate importantly in stabilizing mean ABP in the face offairly rapid perturbations, such as postural adjustments, whereashormonal and autoregulatory mechanisms are thought to dominatein minimizing the effects of challenges that are slower in onsetand more sustained induration.

In this regard, we recently analyzed the relationship between renal sympathetic nerve activity (SNA) and ABP in the "frequencydomain" and found that these two signals were tightly coupledin the unanesthetized rat within a narrow range centered $approx$ 0.4Hz (2). At $approx$ 0.4 Hz, there is a spectral peak in both the ABPspectrum and the SNA spectrum. We explain this 0.4-Hz rhythm asa feedback oscillation inherent within the baroreflex using asimple mathematical model (3, 4). The model predicts thisoscillation on the basis of the experimentally measured time delayin the sympathetic limb of the baroreflex. The linearity of themodel suggests that there is a strong linear coupling betweenSNA and ABP. Interestingly, the experimentally measured couplingbetween SNA and ABP appeared to decrease dramatically at lowerfrequencies. Our original study, however, was based on 9.56-minlong data recordings, which did not permit us to examine thisphenomenon critically at frequencies <0.1 Hz. In this paper, wewill use the term "very low frequency" range to represent thefrequency range f < 0.1Hz.

Another very interesting observation within the frequency domain is that the power in cardiovascular signals appears to increaseas a function of 1/f for very low frequencies, where $beta$ is the slope of the power spectrumcurve on a log-log plot (15, 16). The origin of this "1/fnoise" is not understood. In particular, the role of the autonomicnervous system, if any, in generating this scaling behavior remainsunresolved. On the one hand, sinoaortic denervation (SAD) of thebaroreceptors leads to an enhanced blood pressure variability(6) and to a change in the $beta$ exponent in the very low frequencyrange (7). However, Wagner and Persson (20) recently showedthat autonomic blockade restored the shape and absolute powerof the 1/f noise in the very low frequency range in the SADanimal.

Gaussian fractal noise (or 1/f noise) is stationary. One property of a stationary signal is that its Fourier components haverandom phases (24). A coherence between phases of differentfrequencies can be generated by a transient fluctuation (e.g.,an artifact or a physiological shift produced by transient physicalactivity) or by nonlinear dynamics. Intuitively, nonlinear dynamicsproduce phase coupling because the nonlinear interactions willmix different frequencies together. Classical spectral analysisassumes stationarity so that one can average over data segmentsto reduce uncertainty in spectralestimates.

In the present experiment we sought to quantify the interactions between SNA and ABP in the awake, undisturbed animal withinthe very low frequency range. To these ends we recorded SNA andABP in unanesthetized rats for 2-5 h while they were in theirhome cages. To measure the linear coupling, we computed the magnitudesquared of the coherence between SNA and ABP. Second, we calculatedthe value of $beta$ for both SNA and ABP. To validate our spectralanalysis, we tested for stationarity by computing the "spectralcoherence" (a generalization of ordinary coherence) between thetwo signals (8). We found that for f < 0.1 Hz, the magnitudesquared of the coherence between the two signals approached zero.Moreover, the power law exponent, $beta$ , for the power spectrum ofSNA differs from that for ABP. Assuming that ABP and SNA in theresting rat are "stationary" signals, these results would indicatethat these two signals are not linearly coupled in the very lowfrequency range with periods >10 s. However, the spectral coherenceanalysis revealed significant phase coupling (P < 0.01) betweendifferent frequencies within SNA and ABP, which indicates thatthe two signals are notstationary.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Experiments were performed on six Sprague-Dawley rats (Harlan Industries, Indianapolis, IN) weighing between 330 and 450 g.The standards for care and use of animals of the American PhysiologicalSociety were observed at all stages of thisexperiment.

Surgery

The rats were anesthetized with pentobarbital sodium (65 mg/kg ip) in preparation for implantation of the arterial catheterand renal nerve electrodes using sterile procedures. A Tefloncatheter (#30 LW, ID 0.012; Small Parts, Miami Lakes, FL) wasinserted into the aorta by way of the femoral artery. A sympatheticnerve coursing over the aorta toward the kidney was identifiedthrough a flank incision. A small section of this nerve, usuallyfrom the cephalad angle formed by the renal artery and aorta,was dissected free of connective tissue and placed on fine, closelyspaced (0.4-0.8 mm), bipolar gold electrodes (A-M Systems, Seattle,WA). The exposed nerve and electrode were encased in silicon gel(Wacker Chemie, Munich, Germany). The distal ends of the catheterand wires soldered to the end of the electrodes were tunneledunder the skin, exited at the nape of the neck, and led througha flexibletether.

Data Acquisition

Data were collected 24 h after surgery in conscious Sprague-Dawley rats while they rested quietly in a cage. The arterialpressure signal from a Cobe transducer attached to the femoralartery catheter was amplified and displayed by a Grass model 7polygraph. The electrical signal from the renal sympathetic nervewas amplified (50 K) and bandpass filtered between 30 Hz and 3kHz by a Grass P511 differentialamplifier.

To obtain accurate measurements from the sympathetic nerve recordings, data were digitized at 10,000 samples/s using a Cache486 microprocessor and Data Translation DT2821-F analog-to-digitalconverter. Data were collected for 2-5 h. The initial highly detailednerve traffic signal was full wave rectified and averaged overevery 10 points to produce a 1,000 sample/s signal. This processretains cumulative information from the initial 10,000 sample/ssignal. The pressure signals were compressed "online" to a 1,000sample/s signal by saving every tenth point. Because we were interestedin the low-frequency range, the data were further compressed to50 samples/s by averaging every 20 data points. Using softwaredeveloped in our laboratory in Visual C++, we carefully removedartifacts from the raw timeseries.

Data Analysis

The confidence in spectral estimates can be enhanced by dividing data into multiple epochs and ensemble averaging. Althoughthis decreases variance and increases confidence, it reduces resolutionbecause the length of the data epoch ultimately determines thelimits of the low-frequency resolution. For our classical spectralanalysis, we used data segments ranging in length from 11 (32,768points) to 87 min (262,144 points), giving a low-frequency resolutiondown to 1.9 × 10⁴Hz.

Auto- and cross-spectral estimates were computed using Welch's method (21). For each variable, a discrete Fourier transformwas computed using the fast Fourier algorithm. Before computingthe discrete Fourier transform, linear trends were removed fromthe data, and data were tapered using the Welch window. Squaredmagnitudes and the products of the computed discrete Fourier transformswere averaged to obtain spectral estimates. Estimates for themagnitude squared of the coherence function between ABP and SNAwere computed as the ratio of the magnitude squared of the cross-spectradivided by the product of the autospectra (13) (refer to equation1). The normalized random error in the magnitude squared of thecoherence |C|² (1) depends on both the number of data segments K and themagnitude of the coherence according to

<FR><NU>&Dgr;‖<IT>C</IT>‖2</NU><DE>‖<IT>C</IT>‖2</DE></FR> = <RAD><RCD>2</RCD></RAD> <FR><NU>(1 − ‖<IT>C</IT>‖2)</NU><DE>‖<IT>C</IT>‖ <RAD><RCD><IT>K</IT></RCD></RAD></DE></FR>

The low-frequency portion of each spectrum was modeled as a power law, namely

<IT>P</IT> ∼ 1/<IT>f</IT>&bgr;

where P is the power spectral density, and f is the frequency. To aid in characterizing this "fractal" or spectrally self-similarregion, we used Yamamoto's coarse-graining technique (5, 23)to minimize the harmonic peaks in the spectrum. The $beta$ exponentwas then determined from the slope of the least-squares fit tothe log-log plot of the coarse-grained power spectrum. The uncertaintyin the fitted parameter $beta$ is given by the square root of the correspondingdiagonal entry in the covariance matrix for the least squaresfit. The fit covered frequencies ranging from 0.001 to ~0.5Hz.

To determine if SNA and ABP are stationary, we calculated the spectral coherence, which is a generalization of the ordinarycoherence (8). The coherence C_xy between two timeseries x(t) and y(t) is defined as

<IT>C</IT><IT>xy</IT>( <IT>f</IT> ) = <FR><NU>⟨<IT>X</IT>*( <IT>f</IT> ) <IT>Y</IT>( <IT>f</IT> )⟩</NU><DE>[⟨<IT>X</IT>*( <IT>f</IT> ) <IT>X</IT>( <IT>f</IT> )⟩ ⟨<IT>Y</IT>*( <IT>f</IT> ) <IT>Y</IT>( <IT>f</IT> )⟩]1/2</DE></FR> (1)

where X( f ) and Y( f ) are the Fourier transforms of x(t) and y(t), respectively. The symbol X* represents the complex conjugate,and the angular brackets $<$ X $>$ denote the expected value of X.This definition of coherence can be generalized to

<IT>C</IT><IT>xx</IT>( <IT>f</IT>, <IT>g</IT>) = <FR><NU>⟨<IT>X</IT>*( <IT>f</IT> ) <IT>X</IT>(<IT>g</IT>)⟩</NU><DE>[⟨<IT>X</IT>*( <IT>f</IT> ) <IT>X</IT>( <IT>f</IT> )⟩ ⟨<IT>X</IT>*(<IT>g</IT>) <IT>X</IT>(<IT>g</IT>)⟩]1/2</DE></FR> (2)

for the spectral coherence within a single time series. C_xx( f, g) measures the correlation coefficient betweentwo different frequencies f and g. The numerator $<$ X*( f ) X( g) $>$ is the generalized spectrum of x(t) (24). Note that |C_xx(f, g)|² $<=$ 1 and that the diagonal is always 1. So, information is onlycontained in the off-diagonal terms. The concept of coherencecan also be generalized to

<IT>C</IT><IT>xy</IT>( <IT>f</IT>, <IT>g</IT>) = <FR><NU>⟨<IT>X</IT>*( <IT>f</IT> ) <IT>Y</IT>(<IT>g</IT>)⟩</NU><DE>[⟨<IT>X</IT>*( <IT>f</IT> ) <IT>X</IT>( <IT>f</IT> )⟩ ⟨<IT>Y</IT>*(<IT>g</IT>) <IT>Y</IT>(<IT>g</IT>)⟩]1/2</DE></FR> (3)

for the spectral coherence between two different time series. Here the numerator is the generalized cross-spectrum. The diagonalterm is simply the ordinary coherence defined in equation 1above.

To compute the spectral coherence, we filtered the compressed time series with an eighth-order Butterworth low- pass filter(cutoff frequency was set equal to 2.0 Hz). We further compressedthe two time series to obtain a 5-Hz sampling rate. Each timeseries was then divided into ~700 segments containing 256 points(or a period of 51.2 s). For each data segment, the Fourier transformwas computed as in the classical spectral analysis above. To obtainestimates of the expected values in equation 2 and in equation3, we formed a matrix by taking the outer product of the appropriateFourier transform pairs and averaging this matrix over the 700datasegments.

When x(t) is a stationary zero mean, Gaussian noise time series, Goodman (9) gave the probability distribution of equation2 as

<IT>P</IT>[‖<IT>C</IT><IT>xx</IT>( <IT>f</IT>, <IT>g</IT>; <IT>K</IT> )‖2 > <IT>c</IT>0] = (1 − <IT>c</IT>0)<IT>K</IT>−1

where c₀ $is in$ [0, 1], and K is the number of segments averaged over. In other words, if x(t) is Gaussian noise, then randomfluctuations will lead to estimates that exceed c₀ in (1 $-$ c₀)^K1 × 100% of the computational values (elements of the matrix).[Note: in our data, the data segments were not statistically independentbecause we used overlapping segments. So, we adjusted the numberof segments according to Welch's correction factor, namely: K $right-arrow$ 9K/11 (21).]

To determine whether a time series is stationary, we made a contour plot of the magnitude squared of the spectral coherence.To calculate the statistical significance of an off-diagonal contourin a plot, we multiplied the probability P of an exceedance bythe number of independent values based on symmetry. For the spectralcoherence between two different signals, the number of independentvalues is 1/2 N², whereas for the spectral coherence within a time series, thenumber of independent values is 3/8 N².

Simulations

To test the efficacy of spectral coherence contour plots to detect nonstationarity, we ran twosimulations.

Narrow-band noise. This was a linear model driven by two independent stationary random sources, namely

<IT><A><AC>x</AC><AC>˙</AC></A></IT>1(<IT>t</IT>) = −<IT>x</IT>1(<IT>t</IT>) + 2&pgr; <IT>x</IT>2(<IT>t</IT>) + <IT>z</IT>1(<IT>t</IT>),

where z₁(t) and z₂(t) are two independent random Gaussian time series with zero mean and unit variance. The linear couplingbetween x₁ and x₂ leads to a resonance oscillation at 1.0 Hz.This model was integrated using a fourth-order Runge-Kutta methodwith a time step of 0.001 s. After discarding the first 1,000time steps to get rid of initial transients, a file was made of1,048,576 points spaced at a sampling rate of 10Hz.

Strange attractor. This model was the Rossler attractor (19) and has both linear and nonlinear coupling between variables. The system is definedby

<IT><A><AC>x</AC><AC>˙</AC></A></IT> = −<IT>z</IT> − <IT>y</IT>,

<IT><A><AC>y</AC><AC>˙</AC></A></IT> = <IT>x</IT> + <IT>ay</IT>,

<IT><A><AC>z</AC><AC>˙</AC></A></IT> = <IT>b</IT> + <IT>z</IT>(<IT>x</IT> − <IT>c</IT>)

The linear coupling between x and y produces an oscillation at 2 $pi$ Hz, whereas z acts as a variable damping term to the x $-$ y system. The parameter a gives rise to positive damping, whichputs energy into the x $-$ y system. As a result of the nonlinearinteractions, the z variable exhibits intermittent, positive amplitudebursts.

We used parameter values a = 0.15, b = 0.20, and c = 10.0. The trajectory was integrated using a fourth-order Runge-Kuttamethod with a fixed time step of $pi$ /100. After discarding the first1,000 time steps to allow the trajectory to fall onto the attractor,a file was made of 1,048,576 points spaced at a sampling rateof $pi$ /10. For both simulations, the data file was divided into8,191 overlapping segments of 256 points each. Then estimateswere computed for the spectral coherences as describedabove.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Filtered time series for SNA and for ABP from rat sds are shown in Fig. 1. These data were passed through an eighth-orderButterworth low-pass filter with a cutoff frequency of 0.2 Hzand compressed to a sampling rate of 0.5 Hz. Both time seriesdisplay large amplitude, intermittent fluctuations separated byquiet periods consisting of smaller fluctuations. In particular,notice the three prominent bursts in SNA and the correspondingfluctuations in ABP at roughly t = 8,500, 9,000, and 9,500 s.The duration of each of these bursts is close to 1 min.

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Fig. 1. Time series for sympathetic nerve activity (SNA; µV) in green and for arterial blood pressure (ABP; mmHg) in red from rat sds. Both time series were passed through a low-pass filter with a cutoff frequency of 0.2 Hz and compressed to a sampling rate of 0.5 Hz. Notice 3 prominent bursts in SNA and corresponding fluctuations in ABP at roughly t = 8,500, 9,000, and 9,500 s. Duration of each of these bursts is close to 1 min.

Spectral Analysis

Log-log plots of typical power spectra for SNA and ABP are shown in Fig. 2, A and B, respectively, for rat sdm. For this analysis,we divided the original data set into 54 segments, each 11 minlong, with 50% overlap. The peaks in both spectra at 7.0 Hz andhigher are associated with pulse pressure. The spectral peak near2.0 Hz is related to the respiratory rate. We (3) and others(11, 12) have shown that the prominent peak in both the SNAand the ABP spectra at ~0.4 Hz is mediated by the sympatheticlimb of the baroreflex. Notice that, as mentioned in the introduction,spectral power increases with decreasing frequency for both SNAand ABP.

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Fig. 2. Power spectra for SNA (A), ABP (B), and squared coherence (C) for rat sdm. Prominent peak in both SNA and ABP spectra at ~0.4 Hz is mediated by sympathetic limb of baroreflex (3). Notice that coherence between SNA and ABP drops to low values for frequencies <0.1 Hz.

The magnitude squared of the coherence between SNA and ABP corresponding to the power spectra from Fig. 2, A and B, is shownin Fig. 2C. The confidence interval around a computed coherencevalue depends on the coherence value. For example, the 95% confidenceinterval for a squared coherence value of 0.8 is 0.74-0.86, whereasthe 95% confidence interval for a squared coherence value of 0.2is 0.06-0.34. For each of the three peaks in spectral power associatedwith pulse pressure (~8 Hz), respiration (~2 Hz), and the baroreflex(~0.4 Hz), there is a corresponding peak in the coherence. Noticethe apparent lack of coherence at very low frequencies <0.1 Hz,where the majority of spectral power within SNA and ABPexists.

The least-squares fit to the coarse-grained power spectrum of SNA from rat sdm is shown in Fig. 3A. Recall that the coarse-grainingalgorithm minimizes the spectral power attributable to periodicsources, such as the 0.4-Hz rhythm, so that the 0.4-Hz rhythmseen in Fig. 2A is virtually gone. The surviving power is nowreadily characterized by a power law exponent. However, coarse-grainingdid not eliminate the shelf in the spectrum beginning at ~0.1Hz. To obtain an objective estimate for $beta$ , we performed a nonlinearleast squares fit to a combination of two line segments with twodifferent slopes. The fit covered frequencies ranging from 0.001to ~0.5 Hz and computed the location of the point of intersectionso that we did not have to guess where the 1/f trend ended. Theslope of the first line segment for SNA (over the very low frequencyrange) yielded $beta$ = 0.69 ± 0.03. For even lower frequencies, weexpect there to be different slopes for different frequency ranges,but we did not try to fit to frequencies <0.001 Hz because thesefrequencies were influenced by detrending.

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Fig. 3. Coarse-grained power spectra for SNA (A) and for ABP (B) from rat sdm. Least squares fit to low frequencies is shown as a solid line in each plot. Coarse-graining removed 0.4-Hz rhythm, but not "bend" in each power spectrum near 0.1 Hz. Because of bend in both spectra ~0.1 Hz, we performed a nonlinear least squares fit to a "knee" function consisting of 2 line segments with 2 different slopes. We obtained parameter $beta$ from slope of first line segment. For SNA spectrum, $beta$ = 0.69 ± 0.03. For ABP spectrum, $beta$ = 1.14 ± 0.06. Although coarse graining reduced harmonic power at pulse pressure, it by no means eliminated this strong harmonic component in blood pressure.

Similarly, the least squares fit to the coarse grained power spectrum of ABP from rat sdm is shown in Fig. 3B. Again, althoughcoarse graining reduced the harmonic components in the spectrum,it did not remove the "shelf " in the spectrum at ~0.1 Hz. So,we again performed a nonlinear least squares fit to a combinationof two line segments with two different slopes. The slope of thefirst line segment (over the very low frequency range) yielded $beta$ = 1.15 ± 0.06. For this coarse-grained analysis, we dividedthe data set into 10 overlapping segments each of width 44min.

We performed a similar analysis to determine the set of $beta$ s for each remaining rat. As summarized in Table 1, we find thatthe $beta$ exponents for the two variables are significantly different.The (mean ± SD) $beta$ exponent for SNA is 0.66 ± 0.12, whereas the $beta$ exponent for ABP is 1.12 ± 0.14 (P < 0.01, Student's t-testfor paired samples).

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Table 1. $beta$ exponents for SNA and ABP

To summarize our classical spectral analysis, in Fig. 4 we show an ensemble average of the coherence curves between SNA andABP for all six rats. In agreement with earlier work by Brownet al. (2), we find a robust coherence peak between 0.1 and1.0 Hz, but an apparent lack of coherence <0.1 Hz down to ~0.001Hz. Near 0.4 Hz the peak coherence was 0.82 ± 0.08, whereas <0.1Hz the average coherence from all six animals was <0.2.

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Fig. 4. Ensemble average of coherence curves between SNA and ABP for all 6 rats. Notice strong coherence peak between 0.1 and 1.0 Hz. There is an apparent lack of coherence below ~0.1 Hz, although the majority of spectral power in both ABP and SNA resides in these frequencies.

Modeling

Before proceeding to the generalized spectral analysis of these same data sets, we first consider two simulations. The powerspectrum for variable x₁ in the narrow-band noise simulation isshown in Fig. 5A. The spectrum for x₂ is identical. The peak inthe power spectrum at 1.0 Hz corresponds to the resonance oscilla-tiongenerated by the linear coupling. Figure 5B shows the magnitudesquared of the resulting coherence. In the frequency range wherethe resonance oscillation dominates the background noise, thereis a corresponding coherence peak. The 0.1-Hz rhythm in humans(which corresponds to the 0.4-Hz rhythm in rats) can be describedas narrow-band noise (22). A contour plot of the spectral coherencebetween x₁ and x₂ is shown in Fig. 5C. The diagonal of this contourplot corresponds to the ordinary (i.e., linear) coherence displayedin Fig. 5B. Because there are no nonlinear interactions in thismodel, any off-diagonal structure would be due to random statisticalvariations. For a threshold of c₀ = 0.002, P < 0.01 that the spectralcoherence at any computational node would exceed this value bychance. As expected, there are no off-diagonal contours in thisplot of a stationary time series.

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Fig. 5. A: power spectral density for x₁ variable in narrow-band noise simulation. Note harmonic peak at 1.0 Hz. Power spectral density for x₂ variable (not shown) is identical. Squared magnitude of ordinary coherence between x₁ and x₂ is shown in B. Linear coupling in model gives rise to coherence peak. Contour plot of spectral coherence between x₁ and x₂ is shown in C. This analysis is a generalization of ordinary coherence analysis. Two contour levels were set at 0.00224 and 0.9 for a significance level of P < 0.01. The diagonal peak near 1.0 Hz corresponds to coherence peak seen in B. Lack of off-diagonal contours correctly indicates that underlying dynamical system is strictly linear and that corresponding time series are stationary.

Next we consider the strange attractor simulation, which involves both linear and nonlinear interactions. Contour plots ofthe spectral coherences for the y(t) and z(t) coordinates of theRossler attractor are shown in Fig. 6. Notice that each contourplot is unique and complementary to the other two plots. The Rosslerattractor does have nonlinear interactions. These non-linear dynamicsproduce phase coupling between different frequencies, which resultsin a nonstationary signal. So, we expect to see off-diagonal structureproduced by this nonlinear coupling. In Fig. 6, the dramatic patternin the off-diagonal contours confirms that this analysis is sensitiveto the presence of nonlinear dynamics.

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Fig. 6. Contour plots for spectral coherences for Rossler attractor: A, spectral coherence between z and y; B, spectral coherence within z; and C, spectral coherence within y. Prominent off-diagonal structure correctly indicates underlying nonlinear dynamics. Contours are color coded with light blue representing highest coherence. All 4 quadrants are displayed to show symmetry of spectral coherence calculation. Diagonal contour has been suppressed in B and C because it contains no information. Notice that quadrant III is image of quadrant I, whereas quadrant IV is image of quadrant II. Finally quadrant IV is not simply an image of quadrant I, but contains novel information.

Generalized Spectral Analysis

Contour plots for the spectral coherences of rat sdm are displayed in Fig. 7. Figure 7A represents the spectral coherencebetween SNA and ABP (equation 3), Fig. 7B represents the spectralcoherence within SNA (equation 2), and Fig. 7C represents thespectral coherence within ABP (equation 2). The contour levelsare color coded, with light blue contours representing the highestcoherence (i.e., coherence $>=$ 0.8). In Fig. 7A, the light bluecontour near 0.5 Hz on the diagonal represents the "0.4 Hz" coherencepeak for this rat seen in Fig. 2B. Notice that the diagonal structureends below ~0.1 Hz in agreement with our ordinary coherence analysis.The small red diagonal contours near the origin represent a small,but statistically significant (P < 0.05) linear coherence betweenSNA and ABP in the very low frequency range. The green off-diagonalcontours represent coherences between very low frequencies inSNA and frequencies ~1.0 Hz in ABP, with a statistical significanceof P < 0.01. In Fig. 7B, the most significant off-diagonal contours(in light blue) are confined to the low frequencies within SNA.Notice how the pattern of off-diagonal contours in Fig. 7C complementsthe pattern of off-diagonal contours in Fig. 7B.

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Fig. 7. Contour plots for spectral coherences of rat sdm: A, spectral coherence between SNA and ABP; B, spectral coherence within SNA; and C, spectral coherence within ABP. Note significant off-diagonal structure in all 3 plots. Contours are color coded with light blue representing highest coherence. In A, diagonal contour formation represents linear coherence associated with 0.4-Hz frequency band. Diagonal contour has been suppressed in B and C because it contains no information. Notice qualitative similarity between this figure and Fig. 6 for strange attractor.

A summary of our findings for nonlinear phase coupling is shown in Table 2. In three of six rats, the contour plots showedsignificant (P < 0.05) off-diagonal contours reflecting nonlinearphase coupling of different frequencies in ABP and SNA as wellas within ABP and within SNA. Of the three remaining rats, one(rat sdk) displayed a well-defined pattern of nonlinear phasecoupling within ABP and another (rat sdt) displayed a well-definedpattern within SNA. In only one (rat sdd) did we fail to detectthe presence of nonlinear dynamics. The detection of nonlineardynamics within ABP is consistent with the finding of nonlinearinteractions within heart rate fluctuations reported by Ivanovet al. (10).

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Table 2. Nonstationarity detected with contour plots of the spectral coherence

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The action of the arterial baroreflex naturally implies a very high (linear) coherence between SNA and ABP. This must be true,of course, because increases in blood pressure reflexly decreaseSNA when this reflex is functioning within its normal closed loop.Although changes in parasympathetic activity might be expectedto confound this relationship, this limb of the nervous systemis apparently modestly involved in cardiac regulation in the Sprague-Dawleyrat (18). We have, in fact, demonstrated that the natural periodicityin both SNA and ABP centered ~0.4 Hz can be explained in thisanimal by using a simple linear mathematical model involving onlythe sympathetic limb of the baroreflex (3). Therefore, thepresent findings of a very high coherence between SNA and ABPcentered ~0.4 Hz dramatically affirm this fundamental physiologicalprinciple.

Classical spectral analysis can be misleading, however, when the time series being analyzed is nonstationary. The 0.4-Hz rhythmis relatively stationary, and the ordinary coherence correctlyidentifies the linear coupling between SNA and ABP mediated bythe baroreflex. However, the coupling between SNA and ABP <0.1Hz is obscured in the classical spectral analysis by the intermittentnature of the time series for both variables. Visual inspectionof the raw data shows that SNA comes in intermittent bursts (Fig.1; see also Ref. 2). During many of these bursts there is acorresponding fluctuation in ABP. Because the bursts in SNA areintermittent, they are present in some data segments, but areabsent in many others; as a result, the direct coupling betweenSNA and ABP is washed out by averaging. Such intermittent behaviorcan be produced by simple nonlineardynamics.

Our finding that SNA and ABP are not stationary implies that their time series cannot be characterized by the $beta$ exponentsof their corresponding power spectra. That is, at the start ofthe very low frequency range, SNA and ABP cannot legitimatelybe modeled as fractal Gaussiannoise.

Limitations

Our generalized spectral analysis of the phase coupling between frequencies covered the frequency range from 2.0 to 0.02 Hz.So, we can only say that SNA and ABP are nonstationary withinthis frequency range. Perhaps at frequencies <0.02 Hz, the timeseries are stationary noise. In addition, it must be noted thatour measurement of SNA is actually renal SNA. It is possible thatSNA to other vascular beds (e.g., skin and muscle) contributeto very low frequency ABP fluctuations that are uncorrelated withrenalSNA.

Perspectives

Taking into account the nonstationarity of SNA and ABP helped us understand the results of our classical spectral analysis.That is, the direct coupling between SNA and ABP at frequencies<0.1 Hz is hidden by the intermittent nature of the time series.Perhaps the nonstationarity of ABP can provide insight into theresults of SAD experiments. It is well known that SAD of baroreceptorsleads to an enhanced blood pressure variability and to a changein the $beta$ exponent at very low frequencies (6, 7). Recentexperiments by Just et al. (14) show that the increased bloodpressure variability is generated by the central nervous systemand can be eliminated through ganglionic blockade. However, Wagnerand Persson (20) showed that autonomic blockade restored theshape and absolute power of the 1/f noise in the very low frequencyrange. They concluded that this lower frequency 1/f noise doesnot appear to be directly modulated by the baroreceptor feedbackloop. Seemingly, we have a paradox: the central nervous systemcan influence very low frequency fluctuations in ABP, but doesnot seem to directly mediate these fluctuations in the intact,resting animal. We would argue that the shape of the power spectrumdoes not necessarily characterize ABP fluctuations because thephases of the Fourier modes are not random in an intact animal.Accordingly, denervation followed by ganglionic blockade couldaffect the nature of ABP fluctuations without changing the shapeof the ABP powerspectrum.

The underlying dynamics of the baroreflex and sympathetic nervous system are imprinted on SNA and ABP regardless of the coupling(linear and/or nonlinear) that exists between them. Specifically,the intermittent nature of SNA reflects some sort of underlyingnonlinear dynamics that produces the observed phase coupling betweendifferent frequencies within SNA. Such intermittent behavior occursin simple nonlinear models. Notice the qualitative similaritybetween Fig. 6 for the Rossler attractor and Fig. 7 for rat sdm.The z variable is analogous to SNA, whereas the y variable isanalogous to ABP. Both the z variable and SNA occur in "bursts."In the Rossler attractor, the z variable exerts nonlinear controlover the x $-$ y system through energy dissipation. The y variableis a controlled variable in the sense that it fluctuates withina limited range. Just as in the Rossler attractor, the sympatheticnervous system exerts control over the cardiovascular system throughconcentrated bursts of activity, which result in energy dissipationin thearterioles.

	ACKNOWLEDGEMENTS

We thank Professor Kevin Donohue, Department of Electrical Engineering, for suggesting the application of spectral coherenceto ourdata.

	FOOTNOTES

This work was supported by National Aeronautics and Space Administration Experimental Program to Stimulate Competitive Research(EPSCoR) Grant WKU 522611-95 to the Center for Biomedical Engineering,Kentucky Spinal Cord and Head Injury Trust Fund Grant RB-9601-K3to the Department of Physiology, American Heart Association (KentuckyAffiliate) Postdoctoral Fellowship KY-97-F-7 to D. E.Burgess.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: D. R. Brown, Center for Biomedical Engineering, University of Kentucky, Lexington, KY 40506-0070 (E-mail: randall{at}pop.uky.edu).

Received 16 July 1998; accepted in final form 6 May 1999.

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				D. R. Brown, L. A. Cassis, D. L. Silcox, L. V. Brown, and D. C. Randall Empirical and theoretical analysis of the extremely low frequency arterial blood pressure power spectrum in unanesthetized rat Am J Physiol Heart Circ Physiol, December 1, 2006; 291(6): H2816 - H2824. [Abstract] [Full Text] [PDF]

				D. C. Randall, B. R. Baldridge, E. E. Zimmerman, J. J. Carroll, R. O. Speakman, D. R. Brown, R. F. Taylor, A. Patwardhan, and D. E. Burgess Blood pressure power within frequency range ~0.4 Hz in rat conforms to self-similar scaling following spinal cord transection Am J Physiol Regulatory Integrative Comp Physiol, March 1, 2005; 288(3): R737 - R741. [Abstract] [Full Text] [PDF]

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				D. E. Burgess, D. C. Randall, R. O. Speakman, and D. R. Brown Coupling of sympathetic nerve traffic and BP at very low frequencies is mediated by large-amplitude events Am J Physiol Regulatory Integrative Comp Physiol, March 1, 2003; 284(3): R802 - R810. [Abstract] [Full Text] [PDF]

				L. J. Badra, W. H. Cooke, J. B. Hoag, A. A. Crossman, T. A. Kuusela, K. U. O. Tahvanainen, and D. L. Eckberg Respiratory modulation of human autonomic rhythms Am J Physiol Heart Circ Physiol, June 1, 2001; 280(6): H2674 - H2688. [Abstract] [Full Text] [PDF]

				J. V. Ringwood and S. C. Malpas Slow oscillations in blood pressure via a nonlinear feedback model Am J Physiol Regulatory Integrative Comp Physiol, April 1, 2001; 280(4): R1105 - R1115. [Abstract] [Full Text] [PDF]

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