Coordinate System

The spherical coordinate system used in this study defines azimuthal angle θ as the counterclockwise angle from the positive x-axis to the orthogonal projection on the xy-plane and polar angle φ measured from the positive z-axis. Spherical coordinates are given as (θ,φ).

Local 3D Orientation

Our method for determining local orientations of objects in a 3D histology image, I, relies on the image intensity gradient, G=[G _x ,G _y ,G _z ] ^T , at each voxel (equation 1). We computed G based on convolution with Gaussian kernels (h, equation 2), similar to Karlon et al. (Reference Karlon, Hsu, Li, Chien, Mcculloch and Omens1999), where σ controls the area of influence (5 μm for all results in this study) and the kernel size (s, −s≤x,y,z≤s) was chosen such that the minimum value of h was 0.01.

(1) $$G_{x} {\equals}h_{x}\, {\ast}\,I,\,G_{y} {\equals}h_{y} \,{\ast}\,I,\,G_{z} {\equals}h_{z} \,{\ast}\,I,$$

(2) $$\!h_{i} \left( {x,y,z} \right){\equals}{{2i} \over {\sigma ^{2} }}{\rm exp}\left( {{{{\minus}\left( {x^{2} {\plus}y^{2} {\plus}z^{2} } \right)} \mathord{\left/ {\vphantom {{{\minus}\left( {x^{2} {\plus}y^{2} {\plus}z^{2} } \right)} {\sigma ^{2} }}} \right. \kern-\nulldelimiterspace} {\sigma ^{2} }}} \right),\,i\in\left\{ {x,y,z} \right\}.$$

We then computed the local dominant orientation within image subregions of size m×m×m. For each subregion, we collected all of the gradient vectors as the set G ^m =[G ₁, … , G _n ] and computed the structure tensor T (equation 3). As we weighted the gradient vectors equally, we simply summed over the subregion. We computed the eigenvalues (|λ ₁|≤|λ ₂|≤|λ ₃|) and corresponding eigenvectors (e ₁, e ₂, e ₃) of T. The eigenvector e ₁, with the smallest magnitude eigenvalue, is the local orientation. This analysis treats G ^m as a girdle distribution in spherical statistics. A girdle distribution of axes is concentrated around a great circle; it is an equatorial distribution (Fisher et al., Reference Fisher, Lewis and Embleton1987). The polar axis of a girdle distribution is the vector normal to the equatorial plane. As image gradient vectors are normal to the surfaces of objects within the image, this polar axis is thus the dominant orientation of objects within the local subregion. The polar axis is the eigenvector associated with the smallest eigenvalue of the structure tensor T (Fisher et al., Reference Fisher, Lewis and Embleton1987).

(3) $${\bf{T{\equals}G}} ^{m} {\bf{G}} ^{{m^{T} }} .$$

Subregion size m defines “local” and is an important parameter in our method. Since biological objects (cells, nuclei, cytoskeletal elements, collagen fibers, etc.) can have a range of sizes, even within a single image, using a fixed m is not ideal. Therefore, we applied an adaptive subregion scale, based on the eigenanalysis of T. We first set minimum and maximum subregion sizes (m _min and m _max, respectively) and divided the image into evenly spaced subregions of size m _min. For each subregion, keeping the centroid fixed, we computed the local T from G ^m , as described above, for m values between m _min and m _max. At each size m, we calculated the shape parameter (γ, equation 4) based on the eigenvalues of T. We selected the subregion size m that produced the minimum γ. Small γ values indicate blob or rod-shaped objects (likely CM) as opposed to plate-like objects (Fisher et al., Reference Fisher, Lewis and Embleton1987). For all of the results in this study, we used an m _min of 30 μm and m _max equal to one-fourth the smallest image dimension. We increased m in 10 μm steps.

(4) $$\gamma {\equals}{{{\rm In}\left( {{{\lambda _{3} } \mathord{\left/ {\vphantom {{\lambda _{3} } {\lambda _{2} }}} \right. \kern-\nulldelimiterspace} {\lambda _{2} }}} \right)} \over {{\rm In}\left( {{{\lambda _{2} } \mathord{\left/ {\vphantom {{\lambda _{2} } {\lambda _{1} }}} \right. \kern-\nulldelimiterspace} {\lambda _{1} }}} \right)}}.$$

As an additional step, after dividing the image into subregions of size m _min, we rejected any subregion with an insufficient mean intensity. This step removes subregions that contain no objects. For this study, we set the intensity threshold based on the global mean intensity of the entire 3D image. For our validation tests, we set the threshold at 1.5 times the global mean intensity and for our ECT images we set the threshold at five times the global mean intensity. Our method requires five input parameters: (1) the standard deviation of the gradient kernel, (2) m _min, (3) m _max, (4) the subregion step size, and (5) the intensity threshold. The major steps of our method are outlined in Figure 1.

Figure 1 Flow chart depicting the major alignment method steps. After preprocessing, the image intensity gradient is computed. The image is divided into subregions of the set minimum window size (m _min). At each subregion centroid, eigenanalysis of the structure tensor for window size m gives the polar axis and shape parameter γ. This process is repeated for m between m _min and m _max. The polar axis with the minimum γ is defined as the local orientation. After computing the local orientation for each subregion, κ and OOP are calculated for the image.

3D Alignment in Whole-Mount Histology Images

The local orientations computed above form the set V=[v ₁, … , v _n ], where n is the total number of orientations. Several methods for measuring alignment in histology images have been proposed. These metrics attempt to determine the degree to which objects are oriented along a common direction. In 2D circular statistics, angular standard deviation can be used to define alignment, where larger values indicate a more isotropic organization (Fisher, Reference Fisher1995). The most common measurement in 2D, however, is the orientational order parameter (OOP, equation 5; Drew et al., Reference Drew, Eagleson, Baldo, Parker and Grosberg2015). An OOP of −1 indicates perfect alignment perpendicular to the mean direction, 0 is random alignment, and 1 is perfect alignment parallel to the mean direction. OOP is based on the cosines between the mean direction and the local orientations (ψ).

(5) $${\rm OOP}{\equals}{2 \over n}\mathop{\sum}{{\rm cos}^{2} } \left( \iPsi \right){\minus}1.$$

Spherical statistics provides an alignment measurement for 3D samples. The Watson bipolar distribution describes axial data, where the positive and negative directions of a vector are equivalent. Bipolar data is predominantly oriented along a principal axis. The concentration parameter (κ) measures the dispersion around the principal axis; larger κ indicates greater alignment (Fisher et al., Reference Fisher, Lewis and Embleton1987). We treated our set of dominant local orientations, V, as a Watson bipolar distribution and computed κ as our alignment measurement (equation 6). The calculation of κ is based on the largest eigenvalue (λ ₃) of the structure tensor computed from V. We additionally computed the principal axis (μ), which is the eigenvector associated with the largest eigenvalue (Fisher et al., Reference Fisher, Lewis and Embleton1987).

(6) $${{\lambda _{3} } \mathord{\left/ {\vphantom {{\lambda _{3} } n}} \right. \kern-\nulldelimiterspace} n}{\equals}{{\mathop{\int}\limits_0^1 {x^{2} {\rm exp}\left( {kx^{2} } \right)dx} } \!\mathord{\left/\! {\vphantom {{\mathop{\int}\limits_0^1 {x^{2} {\rm exp}\left( {kx^{2} } \right)dx} } {\mathop{\int}\limits_0^1 {x^{2} {\rm exp}\left( {kx^{2} } \right)dx} }}} \right. \kern-\nulldelimiterspace} {\mathop{\int}\limits_0^1 {x^{2} {\rm exp}\left( {kx^{2} } \right)dx} }}.$$

We compared κ with the OOP computed for a set of test images. To compute the OOP, we used cos(ψ _i )=v _i ·μ. In addition, we computed the 95% confidence cone major angle (α) surrounding the principal axis. To compute the confidence cone, we followed the procedure detailed by Fisher et al. (Reference Fisher, Lewis and Embleton1987, §6.3.1(ii). As alignment increases, α becomes smaller. The 95% confidence cone is sensitive to the number of orientation vectors. To keep the number of vectors equal between samples, we randomly sampled (with repetition) 100 vectors from V and computed α. We repeated the sampling 25 times and calculated the mean α.

Validation

We tested our 3D orientation method using synthetic fiber images that included added noise to validate μ and κ measurements. Each image was comprised of 200 cylindrical fibers embedded in a 512×512×200 voxel domain, where the voxel size was (1.24×1.24×3.0 μm). Fiber lengths and diameters were selected from normal distributions with a mean of 100 and SD of 20 μm for lengths and a mean of 15 and SD of 2 μm for diameters. We selected the mean fiber diameter based on measurements from our confocal data. Fiber centerline axes were sampled from a Watson bipolar distribution (Chen et al., Reference Chen, Wei, Newstadt, Degraef, Simmons and Hero2015). We varied the principal axis (μ ₀) or concentration parameter (κ ₀) of the sampling Watson distribution to test the accuracy of our method. We expect that the local orientations measured by our method have a μ and κ similar to μ ₀ and κ ₀. To test μ, κ ₀ was fixed to 3.0 and we varied the azimuthal (θ) and polar (φ) angles of μ ₀ between −180° and 180° and 10° and 90°, respectively, and generated one image for each μ ₀ (25 total images). To test κ, μ ₀ was fixed to (135°, 45°) and we varied κ ₀ between 0.25 and 10 (27 total images). We added random, normally distributed noise (mean 0, SD 2 μm) to the centerlines in order to incorporate fiber “waviness.” Fibers were added as solid objects to create a binary image, to which we then added white Gaussian noise (mean 0, variance 0.02). Before computing local orientations, we applied 3D Gaussian blur (SD of 3 μm) to replicate the preprocessing step from the confocal image analyses.

We computed local orientations for each test image using our algorithm described above. To validate μ by our method, we tested for a common principal axis between the orientations measured by our method (V) and the set of prescribed fiber centerline axes (V ₀). We performed this test for each image (n=25) and considered a probability value (p)<0.05 significant to reject the hypothesis of a common principal axis (Fisher et al., Reference Fisher, Lewis and Embleton1987). We then examined correlation between the set of measured principal axes (M=[μ ₁, … , μ ₂₅]) and prescribed principal axes (M ₀=[μ _0,1, … , μ _0,25]), where a coefficient (ρ) of 1 indicates perfect correlation (Fisher et al., Reference Fisher, Lewis and Embleton1987). We also computed the R ² value for the fit of the identity line (y=x) to the measured versus prescribed μ components. To validate κ, we tested whether the sets of V and V ₀ had equal concentrations (Fisher, Reference Fisher1986). This test was performed for each image (n=27) and we considered p<0.05 significant to reject equal κ. We then calculated the Pearson’s coefficient (r) to examine linear correlation between the 27 measured κ and prescribed κ ₀ values. In addition, we computed the R ² value for the fit of the identity line to the measured versus prescribed κ values.

One goal of our method is to quantify the degree of myofiber alignment within 3D histologic images from various formulations or culture conditions. Therefore, we tested the robustness of our alignment metric, κ. We selected six values of κ ₀ for the sampling Watson distribution (1, 2, 3, 6, 8, and 10) and generated five noisy fiber images for each one. For this test, we only included 50 fibers per image to reduce the time cost. The standard deviations of the normal distributions used to select fiber lengths and diameters were both 0. To demonstrate that our alignment measurements were independent of orientation, we varied μ ₀ of the sampling Watson distributions so that the five images had different principal axes. We computed local orientations and κ for each image using our method. For each group of five images with the same input κ ₀, we tested if κ for all of the measured orientation distributions were the same (Fisher, Reference Fisher1986). A p<0.05 rejected the hypothesis of a common κ among all five images.

ECT Generation

Our methods for fabricating linear ECTs using embryonic chick (Tobita et al., Reference Clause, Tinney, Liu, Keller and Tobita2006), embryonic rat (Fujimoto et al., Reference Fujimoto, Clause, Liu, Tinney, Verma, Wagner, Keller and Tobita2011), and human-induced pluripotent stem cells (h-iPSC)-derived cardiac cells (Masumoto et al., Reference Masumoto, Nakane, Tinney, Yuan, Ye, Kowalski, Minakata, Sakata, Yamashita and Keller2016) have been published. In brief, we generated ECTs from h-iPSCs that have been induced to differentiate into CM, EC, and mural cells (Masumoto et al., Reference Masumoto, Nakane, Tinney, Yuan, Ye, Kowalski, Minakata, Sakata, Yamashita and Keller2016). Embryonic chick CM were harvested from day 10 white Leghorn chick embryos. Collected cells (~3.0×10⁶ cells/ECT) were mixed with acid-soluble rat-tail collagen type I (Sigma, St. Louis, MO, USA) and matrix factors (Matrigel; BD Biosciences, Franklin Lakes, NJ, USA). Cell/matrix mixture was performed as follows. (1) Cells were suspended within a culture medium [high (25 mM) glucose modified Dulbecco’s essential medium; Life Technologies, Carlsbad, CA, USA) containing 20% fetal bovine serum (Life Technologies). (2) Acid-soluble collagen type I solution (pH 3) was neutralized with alkali buffer (0.2 M NaHCO₃, 0.2 M HEPES, and 0.1 M NaOH) on ice. (3) Matrigel (15% of total volume) was added to the neutralized collagen solution. (4) Cell suspension and matrix solution were mixed with a final collagen type I concentration of 0.67 mg/mL. Linear embryonic chick or h-iPSC ECTs were constructed using a collagen type I-coated silicone membrane six-well culture plate (TissueTrain; Flexcell International, Hillsborough, FL, USA) and FX-5000TT system (Flexcell International). The center of the silicone membrane of a TissueTrain culture plate was deformed by vacuum pressure to form a 20×2 mm trough using a cylindrical loading post (FX-5000TT); ~200 μL of cell/matrix mixture was then poured into the trough and allowed to gel for 120 min in a standard CO₂ incubator (37°C, 5% CO₂) to form a cylindrical construct. Nylon mesh anchors attached to the TissueTrain culture plate held both ends of the construct in place. Once the tissue gelled, the culture plate was filled with preculture medium [α minimum essential medium (Life Technologies) supplemented with 10% fetal bovine serum (FBS), 5×10⁻⁵ M 2-mercaptoethanol (Sigma) and 100 U/mL Penicillin-Streptomycin (Life Technologies)]. Constructed ECTs were cultured for 14 days with medium change every other day (Fig. 2a).

Figure 2 Example engineered cardiac tissue (ECT) geometries and whole-mount images. a: Linear ECT geometry constrained at the long axis ends by mesh nylon anchors, forming a cylindrical shape. b: 40× paraffin section of a day 14 linear ECT. Cardiomyocytes (CM) are predominantly located at the outer surface. c: Projection of a 10× three-dimensional (3D) linear ECT whole-mount confocal image. d: Large-format ECT (LF-ECT) formed by a polydimethylsiloxane (PDMS) mold. e: LF-ECT removed from the mold. Thin, cylindrical bundles connect at junctions. Green box shows a typical imaging location. f: 40× image of a whole-mount LF-ECT acquired at the bundle midsection. The specificity of 4',6-diamidino-2-phenylindole (DAPI) and cardiac troponin T (cTnT) staining is similar to paraffin sections (b). g: Projection of a 10× 3D LF-ECT whole-mount image. h–j: xy (h), yz (i), and xz (j) views of the LF-ECT in (g). Dashed lines show locations of each section. k, l: Attenuation correction of the cTnT image channel showing an xz section before (k) and after (l). Orientation axes in (c) and (g) provide scale bars. Nuclei are stained blue (DAPI) and CM are stained green (cTnT). Scale bar: 5 mm (a, d, e) 250 μm, (b, c, f–l).

Figure 3 a: Representative alignment example using a synthetic fiber test image. Input principal axis is (−122°,80°) and input κ is 3.0. Computed local orientations are visualized as small lines, where line color indicates the magnitude in the x (green), y (red), and z (blue) directions. b: Spherical histogram of prescribed fiber orientations. The volume of each ray represents the relative count for each direction and the thick red line shows the principal axis. c: Spherical histogram of the measured local orientations. Scale bars are shown as three-dimensional orientation axes: 200 μm.

We generated porous, large-format (LF) ECTs using 6×10⁶ cells from the same h-iPSC cell/matrix formulation. The LF-ECT geometry was formed using a custom polydimethylsiloxane (PDMS) mold (Fig. 2b). The tissue mold was 21×20.5 mm and 2.5 mm in height. Rectangular PDMS posts, 0.5 mm in width, were evenly distributed over seven columns. In odd columns, two posts, 7 mm in length, were evenly placed. In even columns, a centered 7 mm length post was flanked by two 2.25 mm length posts. The arrangement produced a staggered post pattern, vertically offset by 3.5 mm. After autoclaving, the PDMS mold was coated with 1% Pluronic^® F-127 (Molecular Probes, Eugene, OR, USA) for 1 h and then rinsed with phosphate-buffered saline (PBS). The cell/matrix mixture was manually poured into the mold resulting in gel polymerization, similar to linear ECT generation. LF-ECTs were cultured for 14 or 28 days. The LF-ECT has a diamond mesh shape, where thin tissue “bundles” intersect at “junctions” (Fig. 2c). The current analysis only examined LF-ECT linear bundles. We generated h-iPSC sheet geometry using a similar method, where the PDMS mold had anchors along the perimeter and no internal posts.

The h-iPSC used for the sheet and LF geometries were cultured as described in our previous publication (Masumoto et al., Reference Masumoto, Nakane, Tinney, Yuan, Ye, Kowalski, Minakata, Sakata, Yamashita and Keller2016). The h-iPSC used in the linear ECTs, however, were cultured using a Matrigel sandwich protocol, which may produce more mature CM (Zhang et al., Reference Zhang, Klos, Wilson, Herman, Lian, Raval, Barron, Hou, Soerens, Yu, Palecek, Lyons, Thomson, Herron, Jalife and Kamp2012).

Cell Transfection for Optogenetic Pacing (OP)

We transfected linear h-iPSC ECTs with an adeno-associated virus at 500 multiplicity of infection (MOI) that delivered the light sensitive ion channel channelrhodopsin-2 (ChIEF), linked to a TdTomato reporter, assisted by Ad-Null virus co-infection (100 MOI). This transfection generated ECTs containing OP enabled CM. Optimal transfection protocols and OP of h-iPSC CM were confirmed in pilot experiments. We then used chronic in vitro OP starting on day 7 using a custom light-emitting diode array powered by an Arduino microcontroller. We recorded intrinsic and maximal OP beat rates on days 7–13 with custom video software and set the chronic pacing rate 0.5 Hz below the maximum OP rate. Chronically paced tissues were compared with control linear h-iPSC ECTs at day 14.

Tissue Preparation and Imaging

We performed immunohistochemistry (IHC) staining and fluorescent confocal microscopy to obtain 3D images of nuclei and CM in whole-mount ECT samples (Figs. 2d–2e). We fixed ECTs for 30 min at room temperature (RT) in 4% paraformaldehyde. Fixed ECTs were washed in 1% Triton X-100/PBS for 1 h at RT and then blocked with 1% Triton X-100/PBS+10% FBS for 1 h at RT. To stain CM, we incubated with primary antibody cardiac troponin T (cTnT, ab45932; Abcam, Cambridge, UK) 1:300 in 1% Triton X-100/PBS+10% FBS+0.2% sodium azide overnight at 4°C followed by a wash with 1% Triton X-100/PBS+10% FBS, incubation with donkey anti-rabbit IgG secondary antibody and then Alexa Fluor 488 conjugated overnight at 4°C. We stained nuclei with 4',6-diamidino-2-phenylindole (DAPI) for 30 min. After IHC staining, we incubated ECTs with 100% glycerol overnight followed by 75% glycerol for 2 h. We then cleared ECTs for 2 h in a solution of 53% benzyl alcohol, 45% glycerol, and 2% DABCO (1,4-diazabicyclo[2,2,2]octane, an antioxidant to preserve dye lifetime) and then changed to fresh clearing solution overnight. This clearing solution has been described previously (Clendenon et al., Reference Clendenon, Young, Ferkowicz, Phillips and Dunn2011) and does not require ethanol dehydration. Processed samples were stored in clearing solution at 4°C.

We acquired confocal z-stacks of whole-mount ECT samples with a Nikon ECLIPSE Ti Confocal System (Nikon, Tokyo, Japan) attached to a Nikon Ti-E inverted microscope platform. Images were captured at 1024×1024 pixel density and 3 μm z-step with a 10×0.3 NA objective using Nikon NIS Elements AR software (Nikon). Laser excitation wavelengths were 405 nm for DAPI and 488 nm for cTnT. ECTs were placed in a 10 mm glass bottom dish (Fisher Scientific, Hampton, NH, USA) filled with clearing solution during imaging. Because the refractive indices (RI) of the tissue and imaging medium must be equal for accurate 3D image acquisition, we measured the RI of processed ECTs using optical coherence tomography (Thorlabs, Newton, NJ, USA) and adjusted the clearing solution to match (Tearney et al., Reference Tearney, Brezinski, Southern, Bouma, Hee and Fujimoto1995). Due to the RI mismatch between the objective (air) and medium (RI=1.52), the actual z-distance scanned inside the tissue is greater than our nominal z-step of 3 μm. To calculate the true distance between slices in the z-stack, we multiplied our nominal z-step by the ratio between the medium and objective RIs (Diaspro et al., Reference Diaspro, Federici and Robello2002). This corrected z-distance (4.56 μm) was used as the voxel z-dimension in our analysis. Both the x- and y-voxel dimensions were 1.24 μm.

Acquisition time for a 100-slice z-stack was ~54 min. We set a maximum acquisition time of 2 h and adjusted the stack size based on this limit. For thinner LF-ECT samples, we were able to acquire the entire tissue. Because linear ECTs were thicker we acquired z-stacks to just beyond the midpoint depth. As our tissues were symmetric, these truncated z-stacks did not affect our measurements. A typical z-stack was 150 slices (679 μm). Images were acquired at 12-bit pixel depth and converted to 8-bit during processing to reduce memory cost. Before applying our orientation method, we corrected image attenuation (Biot et al., Reference Biot, Crowell, Hofte, Maurin, Vernhettes and Andrey2008) and reduced image noise using a 3D low pass Gaussian blur (SD 3 μm). These preprocessing steps were performed on the cTnT image with ImageJ (NIH, Bethesda, MD, USA).

Linear ECTs and LF-ECT bundles were cylindrical and we computed orientation vectors based on the cylindrical coordinate system defined by the ECT medial axis. To calculate the medial axis, we merged the DAPI and cTnT images and then manually segmented the whole ECT volume with Seg3D (Scientific Computing and Imaging Institute, 2015). We then extracted the medial axis based on the distance transform of the binary image (Schena & Favretto, Reference Schena and Favretto2007; Kerschnitzki et al., Reference Kerschnitzki, Kollmannsberger, Burghammer, Duda, Weinkamer, Wagermaier and Fratzl2013), smoothed the axis (Garcia, Reference Garcia2010, Reference Garcia2011) and fit a piecewise spline. For a given point x in the ECT, we computed the location p on the medial axis with tangent vector t that satisfied (x−p)·t=0. The axial vector at x was then defined as t, the radial vector as x−p and the circumferential vector as t×(x−p). After collecting the gradient vectors G ^m for a subregion, we transformed to the local ECT coordinate system, where x is the subregion centroid, and then proceeded with the structure tensor analysis.

We implemented our 3D orientation analysis in Matlab (version 8.3.0.532; Mathworks, Natick, MA, USA) using a MacBook Pro laptop (OS×10.9.5; Apple Inc., Cupertino, CA, USA) with a 2.3 GHz Intel Core i7 processor and 16 GB 1600 MHz DDR3 RAM. The raw ND2 files generated during confocal imaging were imported using BioFormats (Linkert et al., Reference Linkert, Rueden, Allan, Burel, Moore, Patterson, Loranger, Moore, Neves, Macdonald, Tarkowska, Sticco, Hill, Rossner, Eliceiri and Swedlow2010). For the 512×512×200 voxel validation images, computation time was 8 min per image, where the gradient operation took 45 s. When generating the kernels for the gradient computation, we used the same voxel spacing as our confocal image data to maintain constant μm units. Results are presented as mean±SD. We performed two-tailed t-tests to examine differences in alignment between ECT groups; p<0.05 was considered significant.