2.1.

Imaging system, Data Acquisition, and Preprocessing

All mouse procedures were approved by the Institutional Animal Care and Use Committee of the Children’s Hospital of Philadelphia. Data were obtained from 13 mice with a median of five 5-min runs per mouse (range 2 to 25). The imaging system and procedures have been described previously.^7,19 Briefly, mice were anesthetized with a mixture of ketamine (100 mg/kg) and xylazine (10 mg/kg) before being imaged with the OIS system. The OIS system [Fig. 1(a)] consisted of four, temporally multiplexed light emitting diodes (LEDs, M470L3, M530L3, M590L3, and M625L3, Thorlabs) and a camera (iXon 887 or Zyla 4.2, Andor Technologies), which acquired sequential images ($128\times 128\mathrm{pixels}$) for an overall frame rate of 30 Hz (note that, of the 112 total scans, 25 were performed using the newer Zyla imaging system). The nominal central wavelengths for the LEDs were 470, 530, 590, and 625 nm, respectively; however, individualized spectra for each LED were measured as previously described.¹⁹ The field-of-view is the dorsal surface of the mouse brain [Figs. 1(b) and 1(c)].

Fig. 1

System field-of-view and canonical resting-state functional connectivity networks. (a) System diagram showing the LEDs and camera over the dorsal surface of the mouse brain. (b) False color image and schematic (c) of the mouse brain from above as seen by the system. Around the perimeter is scalp and skull (dark gray in the schematic). The segmented brain is central (light gray in the schematic). Landmarks for atlas registration are shown in red. (d) Example hemodynamic time series of changes in total hemoglobin concentration in the mouse brain. Note that the right and left motor cortices are highly correlated ($r=0.93$) and the left motor and visual cortices are uncorrelated ($r=-0.46$). (e)–(h) Exemplary seed-based resting-state functional connectivity maps (seeds highlighted in yellow) showing canonical networks.

The initial analysis follows previously published methods (Fig. 2).^7,19–21 Changes in intensity at each pixel in each color illumination were converted to changes in absorption coefficients using a modified Beer–Lambert lab approach and mean diffuse pathlengths calculated using the analytical solution to the diffusion approximation of the radiative transfer equation in a semi-infinite geometry.¹⁹ The brain was segmented using a combination of automatic and manual methods.²⁰ Images were smoothed with a $5\times 5\mathrm{pixel}$ Gaussian filter (standard deviation: 1 pixel), and data were aligned to the Paxinos atlas by aligning landmarks in the images to standard coordinates using an affine transform.²¹ These absorption changes were filtered to 0.01 to 0.1 Hz before spectroscopy was performed using wavelength-censored methods;¹⁹ all data shown use changes in the total hemoglobin contrast (ΔHbT), as this has been shown to have the highest signal-to-noise.^8,19 Data were downsampled to 1 Hz.

Fig. 2

Flowchart of data analysis, including definitions of the variables used in this manuscript. Following prior methods, raw camera data are converted to a normalized time series of changes in total hemoglobin at each pixel $p$ at time $t$: $H(p,t)$. Functional connectivity correlation analysis generates a correlation matrix of correlations between each pair of pixels $p$ and $q$: $R(p,q)$. The new analysis methods of this manuscript involve (1) analysis of temporal autocorrelation to calculate an appropriate variance of each correlation coefficient $V(p,q)$ and resulting $z$ score $Z(p,q)$ and (2) the correction of spatial autocorrelation using control of the FDR to find an appropriate $p$-value threshold for significance.

After preprocessing, the data for each scan consist of time series of changes in total hemoglobin for each pixel $\mathrm{\Delta }[\mathrm{HbT}](p,t)$, where $p$ is an index of all pixels in the field of view ($1,\dots ,P$) and $t$ is an index of time ($1,\dots ,T$). Analysis was performed only on those pixels within the brain segmentation that passed the quality control thresholds. These pixels are defined by a brain mask $B(p)$ consisting of ones (pixels that are analyzed) and zeroes (excluded pixels).

2.2.

Functional Connectivity Analysis

For each run, the global signal was calculated by averaging over all pixels within the brain mask, and this was regressed from all pixels. The time series were then normalized to zero mean and unit standard deviation. Let $H(p,t)$ be the normalized change in total hemoglobin at pixel $p$ and time $t$. Let $R(p,q)=\rho (H(p,t),H(q,t))$ be the Pearson’s correlation coefficient between the time courses and pixels $p$ and $q$ [Fig. 1(d)]. Using these methods, canonical resting-state functional connectivity networks in the mouse are visualized [Figs. 1(e)–1(h)].

As Pearson’s correlation coefficients are not normally distributed, prior to statistical analysis, they are commonly converted to z scores via the Fisher transformation,^12,22 $F(p,q)=\mathrm{arctanh}(R(p,q))$, and

In the absence of autocorrelation, $V(R(p,q))\approx (1-R(p,q{)}^2{)}^2/(T-3)$. Thus in this situation, $Z(p,q)$ reduces to

2.3.

Temporal Autocorrelation

OIS data, like that from fMRI, are temporally autocorrelated, and each point is not an independent observation. This autocorrelation results in an increase in the variance of the Pearson’s correlation coefficient. The resulting uncorrected (naïve) $z$ score is then spuriously elevated, and the distribution of $z$ scores is no longer normal, violating the assumptions that allow the $z$ score to be converted to a $p$-value.

In resting-state functional connectivity analysis, the most common method to account for temporal autocorrelation is often referred to as “Bartlett’s method.”²³ Here the variance is adjusted using “effective degrees of freedom,” $\hat{T}$ such that

$\hat{T}$ is defined using the global average of the autocorrelation time:

The autocorrelation time is calculated for each pixel in each 5-min run as¹²

In practice, this sum is truncated or tapered to avoid spurious correlations at long delay times. We use Tukey tapering with a maximum lag of $2\sqrt{T}.$ However, the Bartlett approximation for the variance under autocorrelation is only accurate under the null hypothesis ($R(p,q)=0$) and when there is little spatial variation in $\tau$.

Due to these limitations, Afyouni et al.¹² developed a more general formulation for the variance of Pearson’s correlation coefficient, which they termed xDF. Assuming stationary covariance (i.e., that the autocorrelation does not change with time), then the cross correlation is defined as

2.4.

Assessing the Effect of Temporal Autocorrelation

First, we assessed how temporal autocorrelation varied across the imaged portion of the mouse brain. We calculated $\tau$ at each pixel in each run to visualize its spatial variance. We then calculated the standard deviation in $\tau$ across all of the mice in the study. We then averaged the OIS hemodynamic signals within regions of interest as defined by the Paxinos histological atlas of the mouse brain.²⁴ We then repeated the above analyses to determine the spatial and interscan variance in $\tau$ for these averaged time series. The autocorrelation time was compared with the characteristic length (square root of the area) of each parcel of the Paxinos atlas via linear regression.

We then converted correlation coefficients to $z$ scores using each of the above three variance formulas (naïve, Bartlett’s method, and xDF). First, null hypothesis data (all correlation coefficients expected to be 0) were generated by correlating every pixel from one mouse against data obtained from a second mouse. Data with true correlations (alternative hypothesis) were simply obtained from the usual procedure of correlating time series obtained within the same run.

We compared the resulting $z$ scores by plotting the $z$ scores from Bartlett’s method and xDF against the original naïve z scores. Normality of the $z$ score distributions (for the null hypothesis data) was assessed using the Kolmogorov–Smirnov statistic. Afyouni et al.¹² predicted that the length of the time series affects how each variance estimate results in false positives; so we performed this analysis both with single runs (of 5 min) and after concatenating 5 runs in the same mice (for 25 min of total data).

2.5.

Computation Time

All computations were performed using MATLAB 2020a on a server with 20 CPUs and 160 GB of RAM. To assess computational efficiency, during the above experiments, the time it took to calculate $V(R(p,q))$ by both Bartlett’s method and xDF was measured using the tic and toc functions in MATLAB. Although open-source code to calculate xDF was made available by Afyouni et al., that code could not be used without modification, as the number of pixels in the OIS experiment is high enough that attempting to calculate the full cross correlation matrix using a single-matrix operation exceeds the allowable maximum variable size in MATLAB. So the use of multiple for loops is necessary, which lengthens the processing time. No parallel processing was used due to complexities of the cross correlation matrices. We thus recognize that the calculated times are a worst-case scenario for xDF.

2.6.

Spatial Autocorrelation and the False Discovery Rate

A common way to determine statistical significance is through control of the type I error, with a threshold of $p<0.05$ being common. However, a typical resting-state functional connectivity study may involve thousands of comparisons between different brain regions. As a typical mouse OIS brain segmentation includes 10,000 pixels, even if the null hypothesis were always true, then 500 pixels would be judged significant by chance alone. Corrections to the $p$-value threshold that control the FWE, such as the Bonferroni correction, are overly conservative in the face of spatial autocorrelation. Commonly, functional neuroimaging studies attempt to adjust for the type I error using RFT.¹³ However, these methods rely on assumptions that may not be met in resting-state functional connectivity data, especially with optical methods; we explore these problems in Sec. 4.

We chose to control the FDR because it results in less conservative inference. Rather than controlling false positives as a percent of total pixels, FDR methods accept that false positives may occur but seek to limit the average number of false positives as a percent of all positive pixels. Let $N$ be the total number of pixels for which the null hypothesis is rejected and $f$ be the number of false positives; then the FDR is defined as the expected value of $f/N$. Using the Benjamini–Hochberg algorithm,²⁵ we can guarantee that for any threshold $\gamma$, the FDR $\le \gamma$. In particular, we use the Benjamini–Yekutieli extension of the Benjamini–Hochberg method to account for the presence of both positive and negative correlations.^17,26

It is important to note that this algorithm is performed once for the entire correlation matrix and not individually on each map from a single seed (i.e., each row or column of the correlation matrix). Furthermore, note that the correlation matrix is symmetric. Thus the only $p$-values considered are those in the lower triangle of the correlation matrix (not including the main diagonal, which necessarily consists solely of correlation values of 1).

We demonstrate the use of this algorithm to determine the threshold for statistical significance using resting-state functional connectivity data, as previously (Sec 2.2). The $p$-values used were generated with both Bartlett’s method and xDF. First, we used data for which the null hypothesis is true by considering correlations between two separate runs or two different mice to calculate the percentage of false positives generated with various FDR thresholds. The allowed FDR was varied between ${10}^{-5}$ and ${10}^{-2}$, and the percentage of positive correlations was calculated for all 6216 possible combinations of runs. The median across runs for all FDRs was determined.

We then used resting-state correlations within the same run to assess how FDR control provides a threshold for seed-based functional connectivity analysis. We examined how the thresholded maps differed when using $p$-values from Bartlett’s method or xDF using a fixed FDR. Finally, we assessed how sensitive the maps were to the choice of FDR. The FDR was varied from ${10}^{-5}$ to ${10}^{-2}$, and we noted at which level a pixel lost statistical significance.

3.1.

Autocorrelation Time

We first assessed variation in the autocorrelation time, spatially across the mouse brain and across mice. Generally, the autocorrelation time was stable across the cerebral cortex [Figs. 3(a) and 3(d)] between 3 and 3.5 s [Figs. 3(b) and 3(e)]. The autocorrelation times tended to be longer in areas of lower signal quality such as in the olfactory bulb, along the anterior midline (underneath a venous sinus), and at the periphery of the brain segmentation, with some pixels having an autocorrelation time near 6 s. Unlike the finding of Afyouni et al. in the human brain, averaging the hemodynamic time course across regions of interest defined by the Paxinos atlas reduced variation in the autocorrelation time across the cerebral cortex [Figs. 3(c) and 3(f)]. Parcellation also lowered the autocorrelation time, especially in the areas of the brain with lower signal-to-noise around the periphery.

Fig. 3

Example of autocorrelation time maps across the mouse cortex. (a) The autocorrelation in each pixel. (b) Histogram of the data in (a) demonstrating that the majority of pixels have an autocorrelation time of 3 to 3.5 s with a long tail of pixels with higher correlation times. The median autocorrelation time was 3.28 s (interquartile range: 3.16 to 3.54). (c) Autocorrelation times for hemodynamic traces for regions of interest defined by the Paxinos histologic atlas of the mouse brain. The median autocorrelation time within parcels was 2.53 s (interquartile range: 2.05 to 2.93). (d)–(f) Similar results for (a)–(c) for a second example mouse. For the unaveraged data, the median autocorrelation time was 3.27 s (interquartile range: 3.12 to 3.43). For spatially averaged data, the median autocorrelation time was 2.08 s (interquartile range: 1.78 to 2.62).

Similar findings were seen when the maps of the autocorrelation time were averaged across mice. The autocorrelation time was even across the cortex with higher values in the olfactory bulb, midline, and periphery [Fig. 4(a)]. These areas of higher autocorrelation time were also regions of higher standard deviation across mice [Fig. 4(b)]. Again, parcellation with the Paxinos atlas resulted in lower autocorrelations times. With the pixel-wise data, the median autocorrelation time across the brain was 3.46 s (interquartile range: 3.38 to 3.68). After averaging within ROIs, the mean autocorrelation time across the brain decreased to 2.58 s (interquartile range: 2.20 to 2.97 s). The characteristic length (in pixels) of each parcel was inversely related to the autocorrelation time in the parcel ($r=0.72$, $\mathrm{slope}=-0.058$). Although not formally statistically tested, we did not note any major differences in the autocorrelation time measured by the two systems (iXon and Zyla cameras).

Fig. 4

Autocorrelation maps in the mouse cortex averaged across mice. (a) Averaged autocorrelation times. (b) The standard deviation of the autocorrelation time in each pixel across mice and runs. (c), (d) The same analysis as (a) and (b) considering averaged signals in each region of interest from the Paxinos atlas.

3.2.

Temporal Autocorrelation

Next, we compared the effect of different compensations for temporal autocorrelation on the $z$ scores for resting-state functional connectivity matrices. To generate data under the null hypothesis, we correlated data from one mouse to data from another mouse; both scans were 300 s long sampled at 1 Hz. $Z$ scores were calculated using naïve, Bartlett’s method, and xDF [Fig. 5(a)]. In this mouse, Bartlett’s method resulted in an effective degrees of freedom of 45.1. We see that, as expected, Bartlett’s method reduces $z$ scores by this fixed ratio. xDF is similar to Bartlett’s method at low correlation values, with the assumptions in Bartlett’s method being most accurate, whereas at higher correlation values, xDF results in higher $z$ scores. As in Afyouni et al., Bartlett’s method results in the lowest Kolmogorov–Smirnov statistic of 0.0326 compared with 0.238 for naïve and 0.0720 for xDF, indicating that the Bartlett’s method data most closely followed a normal distribution.

Fig. 5

Comparison of $Z$ scores calculated from null hypothesis data using different corrections for temporal autocorrelation. $Z$ scores for both Bartlett’s method and xDF are compared with naïve $z$ scores (the $x$ axis). Bartlett’s method results in a uniform reduction in $Z$ score, whereas xDF preserves high $z$ scores for highly correlated data. (a) Data from two 5-min runs and (b) data from correlating 25 min of concatenated data.

As Afyouni et al. found that the performance advantage of xDF over Bartlett’s method improved with the increasing length of the time series involved, the above analysis was repeated using null data generated by correlating 25 min (5 concatenated 5-min runs) from the same two mice. The results are similar [Fig. 5(b)]. Bartlett’s method had the lowest (most normal) Kolmogorov–Smirnov statistic of 0.060 compared with 0.091 from xDF and 0.266 from naïve. When analyzing high-resolution data, the calculation of variance with Bartlett’s method took a mean of 0.80 s (range 0.73 to 0. 84 s) versus a mean of 17,401 s (about 4.8 h, range 14,541 to 20,037 s) for xDF.

3.3.

Spatial Autocorrelation

First, we again examined the null hypothesis data generated by correlated data from different runs against each other. We compared all 6216 possible combinations of two runs. The number of significant correlations was calculated for each variance correction and for a range of FDRs; the percent of significant correlations was averaged across all comparisons. In this analysis, all of these significant correlations are false positives. First, note that naïve control of the family-wise error rate at 0.05 ($\left|z\right|>2$) results in a substantial number of false positives. With naïve correlation statistics, on average, 67.5% of the correlations from null hypothesis data are significant, compared with 28.0% with Barlett’s method and 38.3% with xDF. Using FDR control resulted in a substantially smaller fraction of correlations being judged significant (Fig. 6). Varying the allowed FDR (from ${10}^{-5}$ to ${10}^{-2}$), we found that, with naïve variance correction, even with an FDR of 10⁻⁵, a median of 9.2% of correlations were still considered statistically significant. Similarly, with this FDR and xDF variance, a median of 4.5% of all correlations were still considered significant. Conversely, using Bartlett’s method, using FDRs below $3.2\times {10}^{-3}$, resulted in a median of zero correlation being significant across null hypothesis pairs of studies. At all FDR thresholds, Bartlett’s method was much more conservative than xDF in null hypothesis conditions (Fig. 6).

Fig. 6

The experimental false positive rate of OIS seed-based functional connectivity data under null hypothesis conditions using different variance corrections for temporal autocorrelation and varying the FDR threshold in the Benjamini–Yekutieli procedure.

We then examined correlation matrices within a run (i.e., actual functional connectivity data with the correlations showing neuronal networks). Using the allowed FDR of 10⁻³ taken from the above analysis, the expected canonical network correlations and anticorrelations are outlined (Fig. 7). Using the $p$-values from Bartlett’s method resulted in a slightly more conservative threshold. Across all scans, using this FDR, xDF resulted in significantly more correlations meeting the threshold for statistical significance (xDF: median 22.3% of correlations, IQR: 17.8% to 26.2% versus Bartlett’s method: median 12.8% of correlations, IQR: 9.3% to 16.2%, $p<0.0001$). In no runs were there any individual pixels that were judged significant by Bartlett’s method but not by xDF.

Fig. 7

Thresholding correlation matrices with control of the FDR at an allowed FDR of ${10}^{-3}$. (a) Example functional connectivity map using a seed in the left motor cortex. (b) Thresholds for significance using $p$-values generated by both Bartlett’s method (green) and xDF (red). Note that Bartlett’s method is more conservative than xDF, and no correlations were found to be significant by Bartlett’s method but not xDF. In this scan, overall 19.7% of correlations were significant by Bartlett’s method, and 29.6% were significant by xDF. In this image (a row of the overall correlation matrix), 43.1% of correlations are significant by Bartlett’s method and 52.7% by xDF. (c), (d) Data from the same run as above, now with a seed in the retrosplenial cortex. In this image (a row of the overall correlation matrix), 41.1% of correlations are significant by Bartlett’s method and 51.7% by xDF.

We then examined how the thresholding would behave with a range of acceptable FDRs. The boundary between significant and non-significant pixels was relatively independent of the exact allowable FDR chosen (Fig. 8). The core canonical regions of each network (and their anticorrelations) were preserved even to an FDR of ${10}^{-5}$. Similarly, even an FDR threshold of ${10}^{-3}$ did not result in significant expansion of the functional connectivity networks. This finding was true regardless of whether Bartlett’s method or xDF was used to generate the $p$-values.

Fig. 8

Effect of varying the allowed FDR on the thresholds for functional connectivity maps. (a) Example functional connectivity map using a seed in the left motor cortex. (b) Using $p$-values derived from xDF, each pixel is colored with the FDR at which that pixel is no longer judged significant. Black areas are where an FDR above ${10}^{-2}$ is required for statistical significance. White areas are where an FDR of ${10}^{-5}$ still results in significance. (c) Similar to (b) except using $p$-values derived from Bartlett’s method. (d)–(f) The same methods as in (a)–(c) now using a seed in the left retrosplenial cortex.