2.1. Acquisition of the SRµCT dataset

SRµCT measurements were conducted at the SYRMEP beamline of Elettra using a multi-scale approach. At SYRMEP the X-ray beam is delivered by a bending magnet source and experiments were performed in a filtered white-beam configuration (filters: 1.5 mm Si, 2.0 mm Al) with a mean energy of ∼27 keV (estimated entrance dose of the order of kiloGray). At the time of measurement, the only microtomographic setup available for pink beam experiments was installed ∼17 m from the source. The mechanical limitation of this setup did not allow a tiling scanning procedure (Du et al., 2018), so only a single scan was acquired for each tooth.

Projections were recorded with a macroscope camera based on a 16-bit, water-cooled sCMOS detector (2048 × 2048 pixels) coupled to a 15 µm-thick LSO:Tb scintillator screen. Using the variable optical zoom of the detecting system, effective pixel sizes of 2.0, 1.3 and 0.9 µm (see Table 1) were set corresponding to fields of view of about 4.1 × 4.1, 2.6 × 2.6 and 1.8 × 1.8 mm, respectively.

For each scan, we acquired 2000 projections over a 180° rotation with an exposure time/projection of 2.0 s (effective pixel size = 0.9 µm) or 1800 projections over a 180° rotation with an exposure time/projection of 1.5 s (effective pixel sizes of 2.0 and 1.3 µm).

The experiment was conducted in propagation-based phase-contrast mode with the sample-to-detector distance set to 150 mm for all measurements, independent of the pixel-size selection.

The slice reconstruction was carried out using the custom-developed SYRMEP Tomo Project (STP) software (Brun et al., 2015).

Before reconstruction, a ring-removal algorithm (Rivers, 1998) was applied. Then, projections were processed by a single-distance phase-retrieval algorithm (Paganin et al., 2002) with a δ/β parameter (ratio between the real and imaginary parts of the refraction index of the material n = 1 − δ − iβ) chosen on an ad hoc basis for a good visualization of fine details in the tooth enamel balancing between contrast and spatial resolution. Since acquisition conditions were not ideal (that is to say homogeneous objects and a narrow X-ray energy bandwidth) a slight blurring can be observed in the reconstructed images. Paganin's algorithm can be employed, with some caution, even on dense and multi-materials (Langer et al., 2014; Arzilli et al., 2015) and with polychromatic light (e.g. Myers et al., 2007). In this case the δ/β ratio was set to 10.

2.2. Virtual histology extraction

The final reconstructed images for histological analyses were generated by importing the volumes in the ImageJ software (Schneider et al., 2012), using the Reslice tool to generate a stack of images following the proper histological sectioning plane (buccolingual plane, passing through the tip of the dentine horn). The image stack was processed through the ZProject average intensity function varying the range of the stack to obtain different virtual thicknesses. In ImageJ, the brightness/contrast tool and the unsharp mask filter were used to enhance visualization of the features of interest, taking care to avoid the creation of artefacts.

2.3. Thin sectioning

The physical sectioning of the deciduous central incisors from the same collection was obtained using standard histological methods (Mahoney, 2015; Nava et al., 2019). The teeth were first cleaned and embedded in ep­oxy resin (Epo-Thin, Buehler Ltd). A longitudinal buccolingual thin section passing through the centre of the cusp, ∼300 µm thick, was obtained using a diamond blade microtome (Leica 1600, Leica AG). The sectioned tooth was attached to a microscope slide, previously treated with liquid silane (3M RelyX ceramic primer), using a light-cured adhesive (3M Scotchbond multi-purpose adhesive) placed under UV light for 60 s. The sections were ground to a final thickness of ∼100 µm with water-resistant abrasive papers of different grits (Carbimet, Buehler Ltd), and then polished with a micro-tissue (Buehler Ltd) and alumina powder (MicroPolish II alumina 1.0 µm, Buehler). The enamel surface of the sections was etched using a phospho­ric acid gel (Etchant Delivery System, 3M Scotchbond) for 10 s, cleaned and finally mounted with a coverslip using Eukitt (mounting medium for microscopic preparations, O. Kindler GmbH & Co.).

Overlapping images of the entire crown were obtained with a microscope camera (Leica DFC 295, 6.55 × 4.92 mm CMOS sensor, 2048 ×1536 pixel imaging, 30 bits colour depth, with an effective pixel size of 0.52 µm when coupled with a 10× objective and 0.63× video optic adapter) paired with a transmitted light microscope (Laborlux S, Leica AG) using polarized light. The images were assembled into a mosaic using Microsoft Image Composite Editor [ICE 2.0 (https://www.microsoft.com/en-us/research/product/computational-photography-applications/image-composite-editor/)].

2.4. Daily enamel secretion rates

DSRs were collected from virtual and physical histological sections. Rates were calculated by measuring the length of prisms between five or six cross striations (representing four or five days of enamel secretion, respectively). This was repeated several times within the enamel regions where cross striations were visible so that a grand mean DSR could be calculated. Overall, a total of 112 DSRs were collected in the virtual thin sections and 51 in the physical thin sections. The Shapiro–Wilk normality test was used to check the normality of the DSR distributions. Non-parametric statistical tests were used to compare the DSR sample distributions because the Shapiro–Wilk test showed that the DSR distribution deviates from normality. The statistical package R (version 4.1.1) (R Core Team, 2021) was used for the statistical analysis and generation of graphs.

3.1. Virtual histology: visualization of the enamel microstructures

A total of 18 synchrotron radiation microtomographic scans were acquired on 9 individual teeth from Velia (Table 1). Overall, the visibility of enamel microstructures in the reconstructed images was good and comparable to that of the physical sections (Fig. 1). Daily cross striations, a neonatal line and other accentuated markings are visible. The anatomical morphology of these features make them recognizable despite of the presence of linear artefacts (even more visible in Fig. 2 as horizontal stripes) related to a non-optimal ring removal procedure.

Figure 1 Velia 376 upper deciduous central incisor, superimposition of virtual histology reformatted slice portions on the classic histology image. Virtual histology: vestibular-lingual reformatted image from SRµCT, isotropic voxel size = 1.3 µm, slice thickness = 13 µm. The yellow line highlights the enamel prism direction, the red line highlights the Retzius line direction.

Figure 2 Velia 387 lower deciduous central incisor. Vestibular-lingual reformatted images from SRµCT, isotropic voxel size = 2.0 µm. Different slice thicknesses (left 2.0 µm, right 40 µm) of the same volume highlight different features. Horizontal lines visible in the images correspond to the plane of the tomographic slices.

Retzius lines and the neonatal line were more visible on slices that are 20–130 µm thick (Fig. 2). Cross striations were more easily discernable in sections where the thickness of the reformatted image is equivalent to the voxel size (Fig. 3). The neonatal line was clearly visible in all the reconstructed and physical thin sections (Fig. 4).

Figure 3 Velia 387 lower deciduous central incisor. Vestibular-lingual reformatted images from SRµCT, isotropic voxel size = 1.3 µm, slice thickness = 1.3 µm. The fine enamel microstructures are discernible. On the right, the magnification of a portion of the left image shows enamel prisms (yellow line) and cross striations (white arrows). Each dark-and-bright couple highlighted by the white arrows represents a single cross striation, i.e. 24 h of enamel deposition.

Figure 4 Velia 96 lower deciduous central incisor. Left: vestibular-lingual reformatted image from SRµCT, isotropic voxel size = 2.0 µm, slice thickness = 20 µm. Center: optical microscopy image of a vestibular-lingual histological section of the same tooth taken with 10× objective magnification (0.52 µm pixel size). Right: vestibular-lingual image from SRµCT, isotropic voxel size = 0.9 µm.

3.2. Comparison of measurements at different voxel sizes of daily secretion rates

We were able to record DSRs in all images reconstructed with isotropic voxel sizes of 2.0, 1.3 and 0.9 µm (Fig. 3). DSRs were determined through multiple estimates for ten virtual histological sections across the entire prenatal portion of the crown.

Fig. 5 shows the boxplots comparing the distribution of DSR values in the virtual (isotropic voxel size of 0.9, 1.3 and 2.0 µm) and physical thin sections from deciduous central incisors of the same skeletal series (Table 2).

Figure 5 Box and whiskers plot of the DSR distributions in classical and virtual histology at different voxel sizes. Virtual 0.9: virtual histology at 0.9 µm pixel size. Virtual 1.3: virtual histology at 1.3 µm pixel size. Virtual 2.0: virtual histology at 2.0 µm pixel size. Bold line – median. N – number of samples.

The Fligner–Killeen test for homogeneity of variance between real histology and different voxel size SRµCT measures shows a statistically significant difference between the DSR variances (chi-squared = 15.658, DOFs [degrees of freedom] = 3, p < 0.05). The Kruskal–Wallis test shows a statistically significant difference between the DSR distributions (chi-squared = 60.327, DOFs = 3, p < 0.01). The pairwise Wilcoxon rank-sum test with continuity correction and Bonferroni correction of probabilities shows no significant difference between the physical sections and SRµCT measurements at 0.9 or 1.3 µm voxel sizes. Significant differences were only detected between physical sections and SRµCT measurements at 2.0 µm voxel size (mean difference = 1.3 µm, p < 0.01). Measurements also differed significantly between the SRµCT measurements at 1.3 and 2.0 µm voxel sizes (mean difference = 0.97 µm, p < 0. 01) and slightly but significantly between 0.9 and 1.3 µm voxel sizes (mean difference = 0.66 µm, p < 0.05).

Overall, the virtual histological assessment of DSRs produces values comparable to those from the physical sections when the smallest voxel size is used. In fact, by increasing the voxel size, the partial volume effect (values of the greyscale levels associated with a single material changing in different parts of the image) is more evident. This artefact can partially mask features of interest if their size is within 2–3 times the voxel resolution and can cause an erroneous measurement of the parameters of interest (Bull et al., 2013; Withers et al., 2021), resulting in larger uncertainty of the DRS values (Table 2).

It is reasonable to compare the mean values between different individuals and between different measurement techniques. In fact, the DSR values obtained from the present virtual histological analysis are in agreement with those already estimated with classical histology for the same population and same tooth class, always in the prenatal enamel [Wilcoxon rank-sum test with continuity correction W = 3159.5, p > 0.05, reference data from the work by Nava, Bondioli et al. (2017)].