In Vivo Tumor Grading of Prostate Cancer Using Quantitative ¹¹¹In-Capromab Pendetide SPECT/CT

SPECT/CT Acquisition and Reconstruction Parameters

All our studies used a commercially available SPECT/CT scanner (Precedence, with a 0.9525-cm [3/8-in] NaI(Tl) crystal thickness and a 16-slice multidetector CT component; Philips Healthcare) installed at San Francisco Veterans Affairs Medical Center. All SPECT data in both phantom and patient studies were acquired using a 128 × 128 matrix with a 4.664-mm pixel size using medium-energy general-purpose collimators. The SPECT acquisition was performed with 64 stops (128 angles by 2 camera heads) at 55 s per stop for a 360° rotation. SPECT reconstructions were performed using an algorithm involving CT-based attenuation correction, and scatter and geometric blurring corrections (Astonish; Philips Healthcare) with 12 iterations and 8 subsets of ordered-subsets expectation maximization. The postprocessing filter of reconstructed images was Hanning with a 1.5 cutoff frequency. In case there was a visual mismatch between the CT attenuation map and the SPECT emission data, the 2 data were manually registered before reconstruction of the final SPECT images. Using the JETStream workstation provided by the scanner manufacturer, each SPECT reconstruction took approximately 30 min each. For patient studies, approximately 185 MBq (5 mCi) of ¹¹¹In-capromab pendetide were administered intravenously, followed by the SPECT/CT acquisitions at approximately 96 h after injection. The helical CT was performed without iodinated contrast agent using the manufacturer's default CT attenuation correction acquisition parameters. The CT data were reconstructed using a filtered backprojection algorithm provided by the scanner manufacturer.

Phantom Preparation

To calculate radiotracer concentrations (Bq/mL) in each voxel of SPECT reconstructed volumes, we performed a SPECT/CT scan of phantoms that were divided into 3 parts: uniform volume, point source, and small and large volumetric lesions. All 3 parts of the phantoms were fit within 1 SPECT field of view to minimize the number of scans needed. The uniform volume was created by partial filling of an aqueous solution of ¹¹¹InCl₃ (53.65 MBq) to test the uniformity of the reconstructed SPECT image and to calculate a conversion factor from voxel values (arbitrary unit) to radiotracer concentrations (Bq/mL). The partial-filling technique was used to ensure complete mixing of the ¹¹¹InCl₃ aqueous solution for the uniformity test. The point source was simulated using a drop of ¹¹¹InCl₃ solution within a small centrifuge tube. This point source was used to measure the spatial resolution of reconstructed SPECT images. The point-spread function was estimated from the spatial resolution value and was an input parameter to the previously developed postreconstruction partial-volume-error (PVE) correction algorithm (15,16). This PVE correction algorithm iteratively compensates PVEs of spill-ins and spill-outs from neighboring pixels by deconvolving the reconstructed volume with the measured point-spread function. The small and large lesions were simulated in phantoms as for prostate gland and bladder and to test our physical correction techniques and PVE correction algorithm to recover known tracer concentrations.

The modified National Electrical Manufacturers Association/International Electrotechnical Commission (NEMA/IEC) body phantom to include bladderlike (146 mL) and prostatelike (7.77 mL) lesions filled with ¹¹¹InCl₃ aqueous solution was prepared in the radiopharmacy laboratory at San Francisco Veterans Affairs Medical Center. At scanning time, activity concentrations for the bladderlike and prostatelike lesions were 32.9 kBq/mL and 636.3 kBq/mL, respectively. The rest of the parts in the body phantom—the body and 6 spheres—were filled with nonradioactive water to simulate attenuation medium. Before phantom filling, all doses were measured using a dose calibrator calibrated for ¹¹¹In. Once the phantom compartments were filled with radioactivity, leak-proof covers and screws were fastened and the phantom was agitated to ensure complete mixing of ¹¹¹InCl₃ with water at room temperature. The bladderlike and prostatelike lesions were manufactured in the investigators' own machine shop at the University of California, San Francisco and were fit in the standard NEMA/IEC body phantom (17).

Patient Recruitment and Pathologic Analysis

Patients were recruited after an institutional review board approved the protocol for collecting image data and other test results related to the imaging studies, including descriptive pathologic evaluation after prostatectomy. Other than the eligibility of prostatectomy, no other restrictive patient selection criteria were imposed.

Advanced Reconstruction and Deconvolution Techniques on Patient Images

We focused on tracer quantification in small volumes such as the prostate gland. In addition, as far as the spatial resolution of ¹¹¹In-SPECT/CT allows, our goal is to develop quantitative indices for each lobe of the prostate gland. Given the often-multicentric distribution of prostate cancer in the gland, even left/right quantitative indices should be useful in characterizing disease. Our choice of reconstruction parameters was based on a preliminary study in which an extra correction term such as attenuation correction in an iterative reconstruction algorithm requires typically twice the iterations to maintain the same signal-to-noise ratio before and after inclusion of the extra correction term (10). Therefore, including CT-based photon attenuation correction and geometric blurring correction as well as scatter correction, we chose 12 iterations—6 times the manufacturer's default number of 2 iterations—of the ordered-subsets expectation maximization algorithm when these 3 correction terms are not included. This advanced reconstruction algorithm was necessary to present good image quality for interpretation of ¹¹¹In-capromab pendetide SPECT/CT studies. The measured spatial resolution was an average of 9 mm in full width at half maximum (FWHM).

However, for tracer quantification within the prostate gland, our volumes of interest were 2 identical cylinders having dimensions of 1.5 cm in both diameter and height at each side of the prostate gland. The volume of interest was smaller than twice the FWHM. Our deconvolution-based postreconstruction PVE correction was necessary to further tighten the errors associated with tracer concentration estimates. Figure 1 illustrates this tightening effect. The top images are before the application of the deconvolution-based PVE correction in transaxial and coronal views; the bottom images are after the PVE correction.

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FIGURE 1. 

Effect of deconvolution-based PVE correction on reconstructed SPECT/CT images. Transaxial (top row) and coronal (bottom row) views before (A) and after (B) PVE correction are shown. Arrows indicate areas of uptake (prostate gland) showing improved spatial resolution after PVE correction.

Antibody Uptake Value (AUV) Correlation with Tumor Grade

The cylindric volumes of interest were drawn completely within each lobe of the prostate gland to calculate the mean value of tracer concentrations in Bq/mL. The tracer concentrations were converted to AUV, which is similar to the standardized uptake value (18) commonly used in PET quantitation. However, AUV is not normalized by individual patient weight because in vivo uptake of antibody such as 7E11-C5 in ¹¹¹In-capromab pendetide is a biochemical characteristic at the level of tissue, which should not vary significantly with patient weight. AUVs were calculated from preoperative data on the prospectively enrolled 10 patients using the following formula:Eq. 1where C′(t_s) is activity concentration (Bq/mL) estimated using the conversion factor from the uniformity measurement and corrected with the 9 mm FWHM iterative deconvolution algorithm, λ_eff is the effective decay constant of ¹¹¹In-capromab pendetide (0.01034 h⁻¹), t_s is the scan time, t_i is the injection time (in h), and A(t_i) is the total activity injected (in MBq). AUV is given in Bq/mL/MBq because this unit provides a user-friendly range of values typically between 20 and 100.

After these AUVs were calculated from patients who went through radical prostatectomy and anatomic pathologic examination after the surgical procedure, we obtained pathologic tumor grades from all these patients. The pathologic Gleason score is often a valuable prognostic factor in prostate cancer management (19). The Gleason grading system assigns a grade from 1 (very well differentiated) to 5 (very poorly differentiated) to the most dominant and second most dominant histologic patterns (20). Comparison was made between higher AUVs (either left lobe or right lobe) and higher grade of the Gleason score because given the limitations of the imaging test in terms of not having finer spatial resolution, smaller segmentation of AUV measurements is difficult to justify. The higher grade of the Gleason score was chosen assuming high AUV can be closely related to intensive PSMA overexpression. As shown in Figure 2, the higher Gleason grade from our 10-patient datasets was either 3 (from 3 + 3 Gleason score) or 4 (either from 3 + 4 or from 4 + 3).

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FIGURE 2. 

Correlation plots of AUVs against Gleason tumor grades from data of 10 patients who underwent preoperative ¹¹¹In-capromab pendetide SPECT/CT and prostatectomy. Gleason tumor grades were obtained from pathologic examination of prostatectomy samples. AUVs were calculated before and after deconvolution-based PVE correction had been applied.

¹¹¹In Concentration Calculation from Small Volumes

The uniform volume after reconstruction using the iterative ordered-subsets expectation maximization algorithm that involved CT-based attenuation correction, scatter correction, and geometric blurring correction resulted in a reconstructed SPECT image with the uniform line profile shown in Figure 3. This line profile was obtained from a transaxial slice stacked over 20 uniform slices. From this measurement, the conversion factors as multiplication factors from the reconstructed image value (arbitrary unit) to the activity concentration (Bq/mL) were estimated as 9.87 and 13.31 for PVE-uncorrected images and PVE-corrected images, respectively. The reconstructed point-source image resulted in an average FWHM of 9 mm using gaussian function fits in all 3 cartesian coordinates. The average FWHM was a mean of 3 values corresponding to 3 cartesian coordinates. Thus, after applying the 9 mm FWHM point-spread function to our iterative deconvolution technique to correct for PVEs as well as the conversion factor from the uniform phantom, we could recover activity concentrations (in Bq/mL) up to approximately 90% of true values in a small prostatelike lesion (7.77 mL) and up to almost 100% of true values in a large bladderlike lesion (146 mL). Figure 4 shows that our PVE correction technique outperforms the non-PVE correction conversion method in the concentration value recovery process.

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FIGURE 3. 

Reconstructed uniform phantom image in transaxial view. Phantom was cylindric. Aqueous solution of ¹¹¹InCl₃ was mixed with water, and the cylindric volume was partially filled to ensure complete mixing with water. Line profile shows fairly uniform intensity pattern except for small dips near edge close to wall.

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FIGURE 4. 

Recovery coefficients were measured using modified NEMA/IEC body phantom containing multiple prostate lesions (smallest, 7.77 mL) and bladder lesion (146 mL). (A) Photograph of modified NEMA/IEC body phantom. (B) Chart comparing recovery coefficients in reconstructed images with and without PVE correction. Deconvolution-corrected measurement significantly recovers tracer concentrations, even in small volume (7.77 mL), whereas deconvolution correction effect is less significant in large lesion (146 mL). (C and D) Reconstructed phantom image slices (transaxial view showing 2 filled lesions) uncorrected (C) and corrected (D) by PVE algorithm are also presented.

SPECT/CT Images of Patients After Advanced Corrective Reconstruction

Figure 1 illustrates this tightening effect. This example shows how the deconvolution-based PVE correction algorithm was necessary to quantify a small volume such as the prostate gland because even the reconstruction algorithm that incorporated photon attenuation, scatter, and collimator response corrections could not provide the necessary spatial resolution to draw values in small volumes of interest. Blurring of the tracer distribution in the prostate gland was significantly improved after the PVE correction was applied.

AUV Correlation with Tumor Grade

Figure 2 shows the correlations between AUVs and Gleason grades of tumors. As the figure indicates, the deconvolution-based PVE correction provides a statistically more significant correlation between the 2 values. The potential result is that ¹¹¹In-capromab pendetide SPECT/CT might be used as an in vivo tumor-grading tool. The Spearman rank correlation test shows that correlation coefficients were ρ = 0.64 and 0.71 for Gleason tumor grade correlation with PVE-uncorrected AUVs and with PVE-corrected AUVs, respectively. The 2-sided P values were 0.055 and 0.033, respectively. Hence, if we consider the statistical significance with a P value of less than 0.05, the deconvolution-based PVE correction needs to be applied to make the correlation results statistically significant using our limited sample size (n = 10).