Twelve adult New Zealand white rabbits (mean weight, at the beginning of the experiment 3.750 g) were evaluated prior to and after an intertrochanteric osteotomy. Immediately prior to surgery, both rabbits’ hips were evaluated by power Doppler sonography and scintigraphy. Prior to each imaging procedure the animals were anesthesized with an intramuscular injection of 11 to 15 mg/kg of ketamine hydrochloride (Ketalar; Parke-Davis, Morris Plains, NJ) and 1.1 mg/kg of xylazine hydrochloride (Rompun; Miles, Shawnee, KS). One of the rabbits’ hips was randomly selected to undergo the surgical procedure. On the seventh day (recent post-operative stage) and sixth week (late post-operative stage) after the surgical procedure, both hips were again imaged with power Doppler sonography and scintigraphy.

Power Doppler Sonography. The rabbits’ hips were scanned in a supine position with an HDI 5000 (Advanced Technology Laboratories Inc., Philips, Bothell, WA) ultrasound scanner using a 10-MHz linear-array transducer. Sagittal and transverse anterior planes were scanned by a single sonologist, using medium filter, pulse repetition frequency of 700 Hz, 79% of color gain, and a depth of 2.9 cm. The transducer was placed on the hip joint region corresponding to the proximal femoral epiphysis and was held in place manually during the performance of the examination. The sonologist could not be blinded with regards to the surgical status (operated vs non-operated) of the hip joints.

Scintigraphy. The animals were injected with tech-netium-99m-labelled methylene diphosphonate (13 MBq / kg). Three hours later, planar projection scintigrams of the hips were acquired using an Orbiter Stand gamma camera (Siemens Gammasonics Inc., U.S.A.), 128 x 128 matrix, fitted with a pinhole collimator that had an aperture diameter of 4 mm. One hundred and fifty thousand counts were obtained per image. Magnified frontal views of the hips were acquired with pinhole collimation at the static phase.

Intertrochanteric Osteotomy Technique. The anesthesized animals were placed in the lateral decubitus position, and a total osteotomy was performed in the intertrochanteric region, followed by internal fixation as described elsewhere5. A single dose of intramuscular penicillin G benzatin, 30,000 U/kg was administered intraoperatively to prevent infection.

Abdominal Aorta Arteriography. Immediately prior to euthanasia of the animals, 5,000 U of heparin was given intraarterially. The abdominal aorta of the anesthesized animals was then catheterized and direct arteriography of both common iliac arteries, superficial and profunda femoral arteries, and their branches was performed with a solution of barium sulfate (Micropaque, Nicholas Laboratories, Slough, England)15. The pelvis and lower limbs of each animal were then radiographed in the anterior-posterior view with the hip in 90° flexion and 45° abduction. This procedure was done to confirm increased vascularity in the operated region at 6 weeks from the surgical procedure.

Power Doppler Sonography. The radiologist interpreting the power Doppler examination was not involved with the interpretation of the radionuclide study. The images were recorded on a digital image processing unit of the ultrasound scanner and were printed out upon the end of each examination. The images were then scanned from the hard copies (Scanner Color Page HR5-PRO Kye Systems Corp, Taiwan) and analysed with a PC computer using Photoshop 5.0; Adobe Systems, Mountain View, Calif. The reproduced images represented similar anatomic regions of the femoral head. In these images, regions-of-interest (ROIs) containing color pixel information were drawn over the area of the femoral head included within the color Doppler box (Fig. 1A-F) by a single operator blinded to all clinical and surgical information, date of examination and results of other imaging tests. The mean intensity of pixels for each ROI of the hip at each time point was calculated with the computer program's histogram function. After determining the mean color pixel intensity within selected ROIs of the two hips, we matched the results with corresponding surgical and temporal information and compared the pixel intensity between the two hips using the following formula: pixel intensity ratio = [(mean pixel intensity within the operated proximal femur - mean pixel intensity within the control proximal femur) / mean pixel intensity within the control proximal femur].

Figure 1.

Corresponding coronal power Doppler sonograms (A-F) and anterior-posterior pinhole scintigraphic (G-L) images of the proximal femura of the same adult rabbit of Fig. 2 and 3 which underwent a left intertrochanteric femoral osteotomy with internal fixation. Please note an increase number of color pixels within the operated proximal femoral epiphysis seen both with Doppler (F) and scintigraphy (L) in the late postoperative images (6 weeks after the surgical procedure). These images show that scintigraphy clearly illustrates the hypervascular process as a consequence of healing in the proximal metadiaphysis of the operated femur starting in the early post-operative stage, at a certain point in a more conclusive way than power Doppler sonography. Nevertheless with regard to the diagnostic accuracy for discrimination of the operative status of the proximal femoral epiphysis our study results demonstrated a greater diagnostic performance for Doppler sonography. Number of color pixels calculated in the region of interest within the operated/unoperated hips in the pre-operative, early and late stages for power Doppler sonography were 1867/1688, 2812/3476, 12557/7560, and for scintigraphy were 61.6/62.2, 44.8/39.4, 63/51.1. The regions-of-interest used for analysis of power Doppler sonography were the squared color boxes (arrows, A) and for analysis of scintigraphy were the circles at the level of the proximal femoral epiphyses (arrow, H).

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Scintigraphy. Regions-of-interest within the proximal femur (Fig. 1G-L) were selected at each time point; the investigator was blinded to the clinical and surgical information, date of examination and results of other imaging studies. A single operator measured the mean intensity of pixels within the ROIs of each hip. The mean pixel intensity results were then matched with the corresponding surgical and temporal information and the following formula was applied: pixel intensity ratio = [(mean pixel intensity within the operated proximal femur - mean pixel intensity within the control proximal femur) / mean pixel intensity within the control proximal femur].

Preparation of specimens. Following euthanasia of the animals with an overdose of pentobarbital, the disarticulated hips were dissected and the proximal femora were fixed with a 10% formaldehyde solution for 24 hours. The proximal femora were then decalcified with a 10% nitric acid solution, dehydrated, and embedded in paraffin. Five mm thick histologic sections were obtained in a plane perpendicular to the physeal growth plate and were stained with Masson's trichrome16 (1) (Fig. 2A-E).

Figure 2.

Photomicrographs of 5 mm decalcified sections of the operated (left hip, B, C) and non-operated (right hip, D, E) proximal femoral epiphyses-physes of an adult rabbit (same as shown in Figures 1 and 3) obtained 6 weeks following a left intertrochanteric femoral osteotomy and internal fixation, stained with Masson's trichrome method (magnification, 40x (B, D) and 100x (C, E). Caption A illustrates the anatomic location of the histologic sections with the physeal cartilage as the anatomic boundary. Please note the extensive area of bone marrow vessels in the operated proximal epiphysis (arrows, C) as compared with the corresponding region on the contrateral hip (arrows, E).

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Histomorphometry. The histologic specimens were evaluated by a pathologist blinded to all clinical and surgical information. Standard methods of point counting under light microscopy were used to quantify vascular fractional area and number of vessels per area unit17,18. Vascular fractional area and the number of vessels per area unit (in mm2) were determined for each specimen by examination of slides under low-power light microscopy. The vascular fractional area was defined as the ratio between number of points of intersection into blood vessels and number of points of intersection into bone tissue. Number of vessels per area unit represented the quantity of vascular points per mm2. The standardized area of analysis included both trabeculae and osteoid within the proximal femoral epiphysis, keeping the physeal cartilage as the anatomic boundary (Fig. 2A-E). The fraction of area and number of vessels per area of the proximal femoral epiphysis were determined in 15 random microscopic fields per histologic section, and were randomly scanned at a magnification of 100x, employing a test eyepiece reticule with 5 parallel lines and 25 points (square lattice test system, 0.902 mm2).

All values were reported as means and standard deviations with individual joints being the experimental units.

Differences in the vascularity of proximal femoral epiphyses that underwent the surgical procedure in comparison with contralateral non-operated epiphyses, assessed by power Doppler sonography or scintigraphy, were evaluated with Wilcoxon rank-sum tests respectively at the pre-operative, 1 week and 6 weeks after the surgical procedure.

Wilcoxon rank-sum tests were also used to evaluate differences in the fractional vascular area and number of vessels per area unit measured in the postmortem proximal femoral epiphyses in operated and non-operated epiphyses.

With regards to histomorphometric methods, receiver operating characteristic (ROC) curves were used to evaluate the ability of vascular fractional area and number of vessels per area unit to discriminate hips that were or were not operated upon by means of the Mann-Whitney U statistic, as well as two-tailed and one-tailed t-tests19.

Concerning imaging methods, ROC curves evaluated the ability of power Doppler sonography and scintigraphy to discriminate hips that had or did not have an operation (threshold: operated vs non-operated hip), and differentiate hypervascular from non-hypervascular proximal femoral epiphyses. Two thresholds, vascular fractional area and number of vessels per area unit (angiogenic potential), were used for the latter differentiation. For assessment of vascular fractional area, cases with a percentage of vessels >11 were considered as positive cases, while those with a percentage of vessels d ≤ 11 were considered negative cases. For assessment of angiogenic potential, cases with >7.8 vessels per mm2 were considered as positive cases and those with d ≤ 7.8 vessels per mm2 as negative cases. Cutoffs were arbitrarily chosen based on expert opinion. Values ≤ 0.50 were indicated as non-diagnostic, > 0.50 and ≤ 0.70 poor, and > 0.70 acceptable diagnostic performance20, 21.

We used AccuROC statistical software version 2.5 (Accumetric Corporation, Montreal, Canada) for the diagnostic test analysis and the SAS® system software package, version 8.2 (SAS Institute Inc., Cary, NC) for the remaining analyses. Results were considered significantly different if the 2-tailed p values were < 0.05.

Visually, all radiographic examinations showed increased vascularity (at different degrees of intensity) in the region of the operated proximal femur as compared with the non-operated contralateral side (Fig. 3).

Figure 3.

Arteriographic images of the vascular system of lower abdomen and lower extremities obtained during forced hyperabduction illustrates the location of the osteotomy as well as the longitudinal orientation of the metallic plate and screws in the proximal femoral diaphysis of an adult rabbit 6 weeks after an intertrochanteric osteotomy which was used for stabilization. Intense vascularity is noted at the healing site (arrow) with contrast opacification of both common iliac arteries, both superficial and profunda femoral arteries, and their branches.

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All the animals recovered from the operation, and no post-operative infection was clinically identified. In two animals the fixation of the metallic plaques was lost and the plaques were released from their original position.

In the pre-operative Doppler and scintigraphy examinations, no differences were noted in the intensity of color pixels representing hip vascularity between the two joints (p=0.54 for Doppler sonography and p=0.92 for scintigraphy) (Table).

In the recent post-operative power Doppler examinations, a tendency towards operated proximal femoral epiphyses presenting with a significantly higher mean number of pixels than non-operated epiphyses (p=0.089) was noted. However, this difference became statistically significant in the late post-operative power Doppler examinations (p=0.049). Conversely, with scintigraphy the mean number of pixels in the proximal femoral epiphyses did not change significantly according to the operative status (non-operated vs operated) in either the recent (p=0.47) or late (p=0.30) post-operative timepoints (Table).

Whereas the vascular fractional area differed between operated and non-operated hips (p=0.01) in the late postoperative stage (6 weeks after the surgical procedure), the mean number of vessels / mm2 did not differ significantly (p=0.26) (Table).

The area under the curve (AUC) of the vascular fractional area (AUC = 0.846 ± 0.099) tended to be greater (p=0.005, 2-tailed; p=0.002, 1-tailed) than the AUC of the number of vessels / mm2 (AUC = 0.358 ± 0.141), suggesting a greater diagnostic accuracy of vascular fractional area to discriminate the operative status of the hips (Fig. 4A).

Figure 4.

Areas under the curve (AUC) of measurements for individual methods of imaging or histomorphometry to discriminate the operative status of the hips are shown. Caption A shows a larger AUC for fractional vascular area (AUC=0.846 ± 0.099) compared with number of vessels/mm2 (AUC=0.358 ± 0.141), however caption Β reveals no significant differences in AUCs between number of pixels of power Doppler (AUC=0.938 ± 0.058) and scintigraphy (AUC=0.688 ± 0.146). For discrimination between epiphyses presenting with large (% of vessels >11) or small vascular spaces (% of vessels ≤ 11) power Doppler performed slightly better (AUC=0.99) than scintigraphy (AUC=0.857 ± 0.099) (C). On the other hand, for discrimination between highly (number of vessels/mm2 >7.8) and poorly (number of vessels/mm2 ≤ 7.8) vascularized epiphyses scintigraphy (AUC=0.984 ± 0.022) performed better than power Doppler sonography (AUC=0.746 ± 0.131) (D).

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Without reaching statistical significance at a two-tailed test (p=0.11, 2-tailed; p=0.05, 1-tailed), the AUC of the ROC curve of power Doppler (AUC = 0.938 ± 0.058) was numerically greater than the AUC of scintigraphy (AUC = 0.688 ± 0.146) in the late post-operative stage, (Fig. 4B) indicating the potential for power Doppler to present a higher accuracy for discrimination between operated and non-operated proximal femura in a study with a larger sample size. Similar results (without reaching statistical significance at a two-tailed test (p=0.15, 2-tailed; p=0.07, 1-tailed) were noted for power Doppler performing better (AUC = 0.99; p= 0.001, 2-tailed; p=0.006, 1-tailed) than scintigraphy (AUC = 0.857 ± 0.099; p=0.02, 2-tailed; p=0.01, 1-tailed) in differentiating epiphyses that encompassed large vascular spaces from epiphyses that presented with small vascular spaces as determined by cutoffs of fractional vascular areas in the late post-operative stage (Fig. 4C).

In contrast, when cutoffs of number of vessels / mm2 were taken into consideration, scintigraphy tended to be more accurate (AUC= 0.984 ± 0.022; p=0.001, 2-tailed; p=0.0006, 1-tailed) than power Doppler (AUC= 0.746 ± 0.131; p=0.1, 2-tailed; p=0.05, 1-tailed) for differentiation between highly vascularized epiphyses (high number of vessels / mm2) and poorly vascularized epiphyses (high number of vessels / mm2) in the late post-operative stage (p=0.07, 2-tailed; p=0.04, 1-tailed) (Fig. 4D).