1. Introduction

To propose a solid recommendation for enhancing the spatial resolution of a gamma camera is always an interesting topic in the field of nuclear medicine. In doing so, an innovated idea of minimum detectable difference (MDD) of gamma camera SPECT (Single Photon Emission Computed Tomography) images was introduced and optimized through the Taguchi analysis and an indigenous V-shaped slit gauge in this study. A bone scan is a common examination (~30% the work load in routine examination) in the nuclear medicine of most Taiwanese hospitals because it can provide bountiful information on local blood flow and bone metabolic activity. This fast-screening tool for whole-body bone cancer metastasis [1,2] is instrumental in examining the preliminary syndrome from increased blood flow or osteogenetic activity enhancement than routine X-ray diagnosis that bone calcium needs to change over ±35–50% in order to cause an apparent lesion in a clinical X-ray examination [3,4]. Nevertheless, bone is one of the most common sites for metastases of all cancers; thus, an optimal preset of regular bone scan protocol can greatly help examine the carcinoma in the early stage from a radiological viewpoint [5,6,7].

Unlike the solid specification of imaging quality for CT scanned image, the criteria of an acquired image in nuclear medicine are less focused, since a gamma camera provides the hot/cold area ratio from absorbing radioactive solution in daily examination. Many researchers have developed various techniques to enhance the quality of scanned images of a gamma camera by pre-/post-processing of the acquired imaging. Oumar and Ercelebi [8] used an indigenous phantom to evaluate the integral and differential uniformity of gamma camera images for quality control. The phantom was customized by many slits or holes of various sizes, and the infused radioactive solution was Tc-99m. Robert et al. [9] adopted a commercial phantom to optimize the spatial resolution of imaging by the practical figure of merit (FOM) and theoretical simulation. Hruska et al. [10] and Dickerscheid [11] also adopted a phantom with multiple holes of various sizes to optimize the quality by justifying the contrast-to-noise ratio and collimator.

The gamma camera imaging can be optimized using Taguchi analysis in this study. The method was adopted in the radiological field for a decade. Yeh et al. [12] first applied this technique to nuclear medicine examination with a semi-quantitative phantom to optimize the imaging quality. Kittipayak et al. [13] combined the idea of MDD with a simple in-house phantom to optimize the imaging quality of head and neck diagnosis in the routine nuclear examination. The Taguchi analysis gained its high reputation in providing efficient and confident solutions with practical verification. Thus, the optimal protocol of gamma camera via Taguchi’s recommendation is always robust, being supported by bountiful numerical proof. The quantified gauge is essential in verifying the optimization because the minimum detectable difference (MDD) adequately represents the spatial resolution. Other benefits of adopting MDD are also mentioned in this study.

2. Materials and Methods

2.1. Taguchi Methodology

The Taguchi methodology is an efficient technique to optimize high-quality feature systems. The specific analysis offers unique orthogonal arrays to contain large factor contributions by processing limited numbers of measurements. The optimal combinations of preset factors for gamma camera scanned imaging were isolated from the surrounding situations or other factors. An ANOVA (statistical analysis of variance) evaluated the factors that significantly affected the main variable. The S/N and ANOVA analyses were integrated to ensure the combinations of factor in optimizing the gamma camera scan protocol [14,15].

2.2. The Orthogonal Arrays

Unlike other optimized methods, Taguchi analysis assure both an optimal level of specific factor from a finite preset of empirical data and those factors that affect the aiming factor. The six factors of the gamma camera scan protocol contained the (A) collimator, (B) Detector to target distance (DTD), (C) total counts (TC), (D) acquired energy width (EW), (E) Matrix size of the acquired image, and (F) Zoom for specific ROI. Thus, a total of 486 (2 × 3 × 3 × 3 × 3 × 3) combinations were considered, since each of these factors would be assigned to two or three levels. Adopting the Taguchi analysis, the measurements were organized to only eighteen groups, which were collected to obtain effects in the similar confidence level as that derived from conventional analysis, via optimal processes [16]. Table 1 shows a standard L₁₈ (2¹ × 3⁵) orthogonal array recommended by Taguchi; the digits in each column indicate the practical organizations or specific levels, for the individual factors (A–F). Table 2 depicts the six factors (A–F) as (A) collimator, (B) DTD (C) TC, (D) EW, (E) Matrix, and (F) Zoom.

2.3. The Analysis of Variance: ANOVA

Taguchi recommended the use of a practical η (loss function) to quantify the outcoming qualities and can easily be converted to a signal-to-noise (S/N) ratio. Larger S/N values corresponded to high-quality features, and the optimal factor combinations produced the highest S/N values [16]. Therefore, the quality feature of gamma camera collected image could be described as below through the specific V-shaped slit gauge by adopting various gamma camera scan protocols:

(1)${\eta }_i=-10\log [{(\frac{1}{Y{\left(i\right)}_{avg}})}^2+{(\frac{stdev}{Y{\left(i\right)}_{avg}})}^2]$

(2)$S{S}_{Total}=\left[\sum _{i=1}^n\sum _{j=1}^r{y}_{ij}^2\right]-n\times r\times {\overline{\overline{y}}}^2$

(3)$S{S}_{Factor}=\frac{n\times r}{L}\sum _{k=1}^L{(\overline{y_k}-\overline{\overline{y}})}^2$

(4)$S{S}_{error}=S{S}_{total}-\sum _{i=1}^{n}S{S}_{Facto{r}_i}$

(5)$Do{F}_{Total}=n\times r-1; Do{F}_{Factor}=L-1; Do{F}_{error}=n\times \left(r-1\right)$

(6)$F_{factor}=\frac{S{S}_{factor}}{Do{F}_{factor}}/\frac{S{S}_{error}}{Do{F}_{error}}$

2.4. V-Shaped Slit Gauge and Gamma Camera

The design of a V-shaped slit gauge ensures a connection with the revised t-test analysis. The zigzag array of the slit with a continuous change of slit depth provides the following gamma-ray image under scanning. Thus, the converted data matrix of derived SPECT can be evaluated for calculating the revised t-test index. Moreover, the data profile of SPECT can be judged channel-by-channel to ensure that two adjacent peaks satisfy the 95% confidence level according to the definition of the revised t-test after the conversion from the original gamma-ray imaging. Thus, the MDD can be quantified as precisely as to one-tenth mm rather than providing an approximate value within 0.3–0.6 mm range of the intrinsic spatial resolution for referring in reality [18].

Figure 1A shows the precise designation chart of this unique PMMA V-shaped slit gauge (200 × 200 × 18 mm³). The V-shaped slit maintains the shallowest depth (2.0 mm) at the top right V-shape then goes deeper along the slit to the very bottom one (4.8 mm). The slit width is designed as fixed 1.0 mm along the pathway. It contains either seven or eight V-shaped triangles on the left or right bottom edges, respectively. The bottom edge width varies in the following decreasing order: right bottom (167 – 134 = 33 mm), left bottom (150.5 − 119.5 = 31 mm), right top bottoms (20 − 15 = 5 mm), and left top bottoms (24.5 − 17.5 = 7 mm). Accordingly, for any vertical tangent line that cuts across both sides of the triangle, one can easily assess its edge distance by the proportional principle, judging from its bottom edge and the distance to the triangular vertex, insofar as the height of each triangle is fixed at 170 mm (185 – 15 = 170 mm). Thus, the MDD of SPECT is defined by quantifying the tangent line from the digitalized image after the SPECT image conversion from the real gamma camera scans.

In contrast to most commercially available planar line phantoms and test patterns, which implied a lead bar to create a hot slit/cold background [19], the V-shaped slit gauge provided the hot-line image with the intense-to-feeble gradation and the wide-to-narrow triangular shape for the imaging quality judgment. Figure 1B shows a 7.4 MBq Tc-99m radioactive solution, which was diluted to 11 c.c. and dyed with blue ink for easier identification; then, it was thoroughly injected into the phantom deepest part to let the solution fill in along the V-shaped pathway for the gamma camera scanning. Figure 1C shows the radioactive V-shaped slit gauge, which was placed in the middle of two water containers. Each container was filled with a 15 cm-thick water layer and mixed with 0.925 MBq Tc-99m for scanning; this is then scanned by the gamma camera, GE Infinia Hawkeye 4 SPECT/CT, as depicted in Figure 1D. In addition, the clinical spine to soft tissue ratio in routine abdomen scan was 37.8 ± 9.5/9.7 ± 9.5 (counts/pixel) = 3.9 ± 3.2 under 95% confidence level from ten randomly chosen patients in hospital, whereas the radioactive intensity of preset V-shaped slit gauge to the background (two water containers were summed together) was 41.8 ± 3.9/11.5 ± 0.9 (count/pixel) = 3.6 ± 0.4, indicating an appropriate ratio preset in this study.

2.5. To Rank the V-Shaped Slit Gauge

A successful gamma camera scanned image with a superior distinguishable difference among V-shaped slits must have a fine resolution and vigorous contrast ratio to detect the fuzzy section. In doing so, three well-trained radiologists (who had over 5 years’ experience in handling the radiological imaging) ranked the acquired gamma camera image in separated three days followed the double-blind criteria, because this process can significantly restrain any biased ranking from an individual radiologist [20]. Thus, the ranking score satisfied the S/N definition “higher-is-better” of the Taguchi methodology (cf. Equation (1)). Moreover, the prompt gamma camera image collected from the default acquisition system was transferred to a specific data matrix and converted by a MATLAB function (/imread) [21] to calculate the exact MDD from the derived SPECT.

2.6. Minimum Detectable Difference and Student’s t-Test Analysis

Most researchers analyze the resolution from SPECT of gamma camera according to the individual FWHM of one peak profile, whereas in this study, the MDD was analyzed by two overlapped peak profiles collected from a tangent slice of the V-shaped slit with two neighboring peaks. Specifically, it is described as the minimum distance between two nearby peak centers via the Student’s t-test with a constant, 1.96, which indicates that the two nearby peak centers separated far enough to create a 95% confidence level of separation [22]:

(7)$\left|X_1-X_2\right|\ge 1.96\times \sqrt{{\left(\frac{FWH{M}_1}{2}\right)}^2+{\left(\frac{FWH{M}_2}{2}\right)}^2}$

A small MDD is always preferable for the gamma camera scan image due to its superior recognizable capability in diagnosing the spine structure. As seen in Figure 2A, two peaks can be recognized as fully separated; (B) two peaks barely passed the Student’s t-test evaluation; nevertheless, in (C), the two peaks are too close to be distinguished. Note that the principle of failing or passing the Student’s t-test are calculated because they are completely built on the calculation results, comparing to other reports, which are mostly stood on the qualitative discrimination of radiologists and may include human factor-biased uncertainties. Therefore, the quantified MDD can provide an auxiliary tool in justifying the performing of gamma camera scanned imaging rather than radiologists’ visual ranking. However, manual judgment is still essential in the preliminary sorting stage of the Taguchi analysis.

3. Results

3.1. Data Analysis

Figure 3 shows the eighteen originally scanned images from gamma camera scan, according to Taguchi’s eighteen groups of factor combinations. The image quality was judged by sharpness, brightness, sensitivity, and contrast ratio altogether. The ideal images should have a strong black-and-white contrast ratio and sharp edges along the V-shaped slit. Most peaks could be easily recognized from peak one to peak six. In contrast, peak seven or eight was dependent. Thus, the precision of peak nine (cf. Figure 1A, 5 mm of the bottom edge) was beyond the most analytical ability of a routine gamma camera. Meanwhile, peak eight (cf. Figure 1A, 9 mm of the bottom edge) was the decisive part, as it would be seen from the following discussion. Table 3 shows the originally ranked grades, averages, standard deviations (stdev), and S/Ns derived by the three radiologists from three separate rounds (Equation (1)). The standard deviations were obtained from the ranked score y_i in every group. Moreover, the average, stdev, and S/N values in eighteen groups were reorganized for every specific factor. For instance, the average score of the groups (1, 4, 7, 10, 13, 16), (2, 5, 8, 11, 14, 17), or (3, 6, 9, 12, 15, 18) implied the effects of factor C (total counts, TT) at different levels (1, 2, or 3) on the performance of gamma camera-collected images (cf. Table 1 and Table 2). The fish-bone plots of average, stdev, and S/N vs every specific factor of the gamma camera scan as illustrated in Figure 4, respectively. Group 2 implied the highest values within eighteen groups, as shown in Table 3. The average, stdev, and S/N values for group 2 were 16.56, 0.88, and 21.88, respectively. Accordingly, the suggested preset of six factors for the gamma camera scanned imaging system contained (A) LEHR collimator, (B) 5 cm DTD, (C) 150 k TC, (D) 16% EW, (E) Matrix size 256 × 256, and (F) 1.28 ZOOM to maintain the highest S/N in each factor (cf. Figure 4, S/N(dB)).

3.2. ANOVA, Analysis of Variance

The derived confidence levels of factors attributed to the virtue of the gamma camera scan were obtained in Table 4. The importance of the dominant factors of the gamma camera scan protocol was analyzed by executing an F-test (cf. Equation (6)). A dominant factor was defined as providing high contribution. Therefore, factors A (collimator) of 38.5% and B (DTD) of 41% were accredited as the most affective to the imaging quality of the V-shaped slit gauge. Moreover, no factors from A to F could be aligned separately to assure high rank because four out of six factors (A, B, E, and F) were significant according to F-test, although factor E (Matrix size) or F (Zoom of ROI) showed a minor contribution (1.4% and 4.0%, respectively, cf. Table 4).

4. Discussion

4.1. Verifying the Taguchi Recommendation by Quantified MDD

Taguchi analysis helps efficiently optimize the gamma camera scanned imaging in the first stage according to the unique eighteen orthogonal arrays. Then, the quantified MDD is provided to verify the optimization process further. The calculated MDD can precisely quantify the performing of scanned images rather than radiologists’ visual judgment in the second stage, although the professional judgment based on the double-blinded principle is practically a reliable tool. Figure 5 demonstrates the three derived SPECT and practical images from gamma camera scanned according to (A) group 2 of the original Taguchi’s eighteen groups and have the highest S/N among eighteen groups, (B) conventional preset, and (C) the combination of the highest S/N in every specific factor (cf. Figure 4, beyond the original eighteen groups). As clearly depicted in case (A) or (B), angles 8 and 9 on the right edge are mixed (cf. Figure 1A top-right edge width was 5 mm). Noteworthy is that the acquired images from a practical gamma camera were mirror-reflected, whereas in case (C), angle 9 was barely identified. Nevertheless, if checking the definition of MDD, none of the three cases can fulfill the criteria of MDD to gain a 95% confidence level from angle 8 and angle 7 (cf. Figure 1A, the bottom edge is 29 − 20 = 9 mm). Thus, we focus on the MDD between angles 7 and 6 (bottom edge is 42 − 29 = 13 mm) because the slit of this triangle has a deeper depth of 2.8 mm than that between angles 7 and 8 of 2.4 mm (cf. Figure 1A). A deeper depth can deposit comparatively more contrast media solution than a shallow one and become a bright image for calculation. Table 5 shows the correlated calculation of MDD between angles 6 and 7 of three cases in this study. The raw data of each acquired image are saved in the same data matrix. Thus, the cm/pixel values are the same in analyzing the specific MDD. Channel No., as adopted in Equation (7), is obtained from the SPECT of a specific case (cf. Figure 5). The second group in the original L₁₈ has the largest MDD since it cannot separate angles 7 and 8. In contrast, the optimal one has the smallest MDD = 7.1 mm, and the conventional one has a medium MDD = 7.9 mm in reality. While derived MDD values may differ insignificantly, the Taguchi methodology still proves its effective capability in optimizing SPECT resolution of gamma camera images. In addition, the three different protocols of the gamma camera are rearranged in Table 6. As demonstrated, only factors are compromised altogether, and can then minimize the MDD in reality. The quantified MDD provides reliable numerical information to help radiologists in routine quality control rather than visual inspection according to commercial phantom or line pair gauges.

4.2. Quantified MDD Superior to Line/Pair

The quantified MDD can be transferred to the line pair/cm (lp/cm) in analyzing the gamma camera collected imaging quality, although these are defined on the basis of different scenarios in theory. The MDD is proposed to identify the minimum distance between two peaks and maintains a 95% confidence level, yet the lp/cm represents two lines of brightness and darkness. Furthermore, the MDD can be theoretically smaller than we derived if the confidence level is reduced from 95 to 68%; then, the constant of 1.96 can be disregarded in Equation (7). As seen in Figure 6, the diagram shows the difference between MDD and lp/cm. The definition of MDD can thus be interpreted as bearing a similar width to one line pair. Thus, the number of lp/cm approximately equals 10 mm/MDD, although MDD provides more precise information. Thus, the roughly estimated lp/cm is 1.2, 1.3, and 1.4 for the second group, conventional, and optimal, respectively. Nevertheless, the lp/cm offered only the digitized number, yet MDD is calculated based on two adjacent peaks from SPECT of the real gamma camera scanned images. In addition, Table 7 shows the various MDDs or lp/cm from other research and this work for comparison. As clearly shown, cardiac X-ray has the finest resolution for diagnosis, whereas a gamma camera is functioned on the collection of radioactive solution inside patient’s body; thus, the imaging has comparatively inferior quality among all.

4.3. Clinical Testification of Gamma Camera Optimal Preset

To further testify the optimal preset of the gamma camera, the scanned image was compared to the conventional preset, as shown in Figure 7. As clearly depicted, the optimal preset yielded clearer images with greater contrast than did the conventional preset. Specifically, the shadow of the ribs and pelvis could be identified, and the sacroiliac joint could also be delineated from the optimal figure. The clinical procedures had been accomplished between June to December 2021 under IRB no. B11002019 approved by the Buddhist Dalin Tuzchi Hospital. The optimization of the imaging system improved the gamma camera images for better clinical examination.

5. Conclusions

This study optimized the minimum detectable difference (MDD) of gamma camera SPECT images through an indigenous V-shaped slit gauge and the Taguchi methodology. The eighteen groups of factor combinations were organized according to Taguchi’s unique orthogonal array and ranked by three well-trained radiologists to derive the signal-to-noise ratio and obtain the fish-bone plot of average, stdev, and S/N, respectively. Then, the MDD was proposed to derive further analysis of the SPECT from gamma camera scanned images. The quantified MDD was 8.4, 7.9, and 7.1 mm for the second group of original L₁₈ preset, conventional, and the optimal preset, respectively, in this study. The fine MDD is beneficial in evaluating the spatial resolution than line pair/cm in routine quality control. However, these two indexes were defined according to different scenarios and could be converted via a simple equation. The clinical examination proved the optimal preset of a gamma camera to have a sharp delineation. The application of MDD to justify the imaging quality in clinical nuclear medicine is expected.

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Figure 1. (A) the precise designation chart of this unique PMMA V-shaped slit gauge (200 × 200 × 18 mm3). The slit width is designed as fixed 1.0 mm along the pathway. (B) A 7.4 MBq Tc-99m radioactive solution is diluted to 11 c.c. and dyed with blue ink for easier identification inside the gauge. (C) The radioactive V-shaped slit gauge was placed in the middle of two water containers. Each container was filled with 15 cm thick water and mixed with 0.925 MBq Tc-99m for scanning. (D) Gamma camera GE Infinia Hawkeye 4 SPECT/CT used in this study.

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Figure 2. (A) The two peaks can be identified as wholly separated. (B) The two peaks barely passed the Student’s t-test evaluation. (C) The two peaks are too close to be differentiated.

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Figure 3. Eighteen original scanned images from the gamma camera according to Taguchi’s eighteen factor combinations. The image quality was judged by sharpness, brightness, sensitivity, and contrast ratio altogether.

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Figure 4. The fish-bone-plots of average, stdev, or S/N versus six factors of the gamma camera scan protocol. The contribution of each factor can be analyzed and reorganized according to the Taguchi unique orthogonal array.

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Figure 5. The three derived SPECT and original images from gamma camera scanned according to (A) group 2 of the original Taguchi’s eighteen groups and have the highest S/N, (B) conventional preset, and (C) the combination of the highest S/N in every specific factor.

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Figure 6. The diagram shows the difference between MDD and line pair/cm. The MDD can be interpreted as having a similar width to one line pair.

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Figure 7. The optimal preset yielded clearer images with greater contrast than the conventional preset. Specifically, the shadow of the ribs and pelvis could be identified, and the sacroiliac joint could also be delineated from the optimal figure.

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