Analysis of the origin and invasion of prostate cancer from autopsy and radical prostatectomy specimens
Highlight box
Key findings
• Approximately 50% of the lesions originate from the apex above 0.5–1.4 cm.
What is known and what is new?
• Without the presence of a pseudocapsule, prostate cancer is invasive in volume growth.
• The study demonstrated the origin location, invasion tendency and morphology of prostate cancer lesions.
What is the implication, and what should change now?
• The results indicated that the center of the lesion can be used as a convincing and recommended concept for describing the morphology of prostate cancer.
Introduction
Multifocality is a prominent feature of prostate adenocarcinoma. On average, there are 2–3 prostate cancer lesions in each organ after radical prostatectomy (1). By comparison, autopsy specimens have 1–2 lesions (2). The index and clinically significant lesions play a vital role in diagnosing and treating prostate cancer (3,4). Without a pseudocapsule, prostate cancer is invasive in volume growth. In general, the spatial distribution of prostate cancer shows some regularity (5). It is the result when prostate cancer develops to a certain extent.
However, prostate cancer’s specific origin, location, and invasive characteristics are unclear. A systematic description of the morphological characteristics of prostate cancer has not been reported in previous studies. Considering that prostate cancer has specific spatial distribution patterns, it is not known whether it is caused by prostate cancer having some regular original distribution or lesions having certain invasive tendencies. Determining the origin and invasion of prostate cancer can improve the understanding of the pathological characteristics of prostate cancer and is also crucial for understanding the relationship between prostate cancer and its surrounding tissues.
Lesions in autopsy specimens are often small in number and size, which have significant advantages for studying the origin of prostate cancer (2,6). Radical prostatectomy specimens can be used to study prostate cancer’s development and invasive tendencies. Considering the difficulty and high cost of obtaining and producing autopsy specimens, clinical specimens with relatively small tumor volumes can serve as good examples. Therefore, the combined study of autopsy and clinical prostate cancer specimens with a small tumor volume can show significant advantages in analyzing prostate cancer’s origin and development.
Whole organ sampling and digital pathological slides provide an essential foundation for analyzing the occurrence and development of prostate cancer (7). We have preliminary research foundations studying on clinical and autopsy prostate cancer specimens and have accumulated a considerable database on whole-organ digital pathological slides (1,2,5). Combined with the above research backgrounds, we are committed to further exploring prostate cancer’s original and invasive characteristics. We present this article in accordance with the MDAR reporting checklist (available at https://tcr.amegroups.com/article/view/10.21037/tcr-23-1752/rc).
Methods
Study population
This study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). This study was approved by the ethics committee of Peking Union Medical College Hospital, Chinese Academy of Medical Sciences (ZS-1546). Informed consent was not needed as patient data were retrospectively reviewed. From June 2013 to September 2016, 192 clinical specimens were selected from Peking Union Medical College Hospital, and 98 were finally included. From September 2017 to February 2019, 124 consecutive autopsy specimens were collected from the Department of Anatomy, Histology and Embryology, Peking Union Medical College, Chinese Academy of Medical Sciences, and 111 met the inclusion criteria. The inclusion criteria for the clinical specimens were as follows: (I) pathological diagnosis of prostate adenocarcinoma; (II) no neoadjuvant therapy before radical prostatectomy; (III) complete capsule and bilateral seminal vesicles; and (IV) tumor volume equal to or less than one-third of the organ volume. The inclusion criteria of autopsy specimens had been described in our previous study (2).
Sample processing and data acquisition
All clinical and autopsy specimens were sectioned and scanned into whole-mount digital slides. The contours of the lesions were delineated, and Gleason scores were calculated. Lesions with a distance of more than 3 mm on the same slice or vertical discontinuous lesions were defined as different lesions (8). Taking the urethra as a boundary, the prostate was divided into the anterior and posterior zones and the left and right halves. Further, it was subdivided into the anterior left, anterior right, posterior left, and posterior right quadrants. The apex was defined as the inferior-most 0.5 cm portion of the prostate. Slides with a thickness of approximately 3 mm were sectioned one by one from the apex to the base, and the remaining 0.5–1 cm of the superior-most part of the prostate was defined as the base (9). In the Gleason grading system, Gleason scores of 6, 3+4, 4+3, 8, and 9–10 were defined as Gleason grade groups 1–5 (10). The lesion with the highest Gleason score was defined as the index lesion. If the Gleason scores were the same, the lesion with the largest volume was regarded as the index lesion (11). Lesions with tumor volume >0.5 cm3, Gleason grade group ≥2, or capsule invasion were defined as clinically significant lesions (12).
As the volume of the prostate organ varies, the number of vertical slices would be different. In the process of sampling, every specimen had at least five slides, including the apex, the apex above 0.5–0.8 cm, the middle slide, the base below 1.0–1.3 cm, and the base, while more than 50% of the specimens had three more slides above the apex and three more slides below the base. Therefore, we selected these 11 slides for research in our study. The slide with the largest tumor area was defined as the center of the lesion. The lesion’s maximum anteroposterior, left-right, and horizontal diameters were depicted and calculated (Figure 1). The maximum vertical diameter = the slice thickness × the number of positive slices. The thickness of the slice = (the vertical diameter of the prostate − actual thickness of the apex − actual thickness of the base)/the total number of vertical slides. The spatial morphology of the lesions was divided into three types: (I) the tumor area gradually decreased from the center of the lesion to both sides; (II) the tumor area gradually decreased from the center of the lesion to one side; and (III) the tumor area developed irregularly from the center of the lesion to both sides (Figure 2).
Statistical analysis
If a normal distribution was met, the data were described by the means ± standard deviations and compared by independent sample t-test. If the data did not conform to a normal distribution, the data were described with the median value and interquartile range (IQR) and compared with the rank-sum test. The Chi-squared test was used to compare the rates. All tests were two-sided, and P<0.05 was considered statistically significant.
Results
General characteristics of prostate cancer lesions
Of the 111 included autopsy specimens, 39 were found to have prostate cancer. The total number of lesions was 67, with an average of 1.7 lesions per specimen. The total number of lesions in 98 included clinical specimens was 268, with an average of 2.7 lesions per specimen. The median volume of 335 lesions in autopsy and clinical specimens was 0.045 mL (IQR, 0.007–0.656 mL), and the median Gleason grade group was 2 (IQR, 1–2). The general characteristics of the lesions are shown in Table 1.
Table 1
Clinical characteristics | Index lesions (n=137), n (%) | All lesions (n=335), n (%) |
---|---|---|
Tumor volume (mL) | ||
≤0.5 | 58 (42.3) | 244 (72.8) |
>0.5 and ≤1 | 20 (14.6) | 25 (7.5) |
>1 | 59 (43.1) | 66 (19.7) |
T staging | ||
T2a | 83 (60.6) | 263 (78.5) |
T2b | 12 (8.8) | 20 (6.0) |
T2c | 21 (15.3) | 27 (8.1) |
T3a | 15 (10.9) | 19 (5.7) |
T3b | 6 (4.4) | 6 (1.8) |
Gleason grade group | ||
1 | 28 (20.4) | 110 (32.8) |
2 | 65 (47.4) | 151 (45.1) |
3 | 21 (15.3) | 35 (10.4) |
4 | 7 (5.1) | 13 (3.9) |
5 | 16 (11.7) | 26 (7.8) |
Clinically significant lesions | ||
Tumor volume >0.5 mL | 79 (57.7) | 91 (27.2) |
Gleason grade group ≥2 | 111 (81.0) | 225 (67.2) |
T staging ≥ T3a | 21 (15.3) | 25 (7.5) |
The origin of prostate cancer lesions
A total of 276 lesions are confined to the horizontal quarter quadrant of the prostate, with 178 having clinical significance. The distribution of these lesions across different prostate volumes (PVs) is presented in Table 2. There were no significant differences in the quadrant distribution for both overall lesions and clinically significant lesions in the groups with all PV sizes, 15≤ PV <30 mL, and PV ≥45 mL. However, in the group with 30≤ PV <45 mL from the anterior zone, the tumor positive rate was notably higher in the left half compared to the right half for both overall lesions (P=0.011) and clinically significant lesions (P=0.005).
Table 2
Variables | All PV sizes | 15≤ PV <30 mL | 30≤ PV <45 mL | PV ≥45 mL | |||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Anterior zone | Posterior zone | Anterior zone | Posterior zone | Anterior zone | Posterior zone | Anterior zone | Posterior zone | ||||
All lesions, n (%) | |||||||||||
Left half | 80 (29.0) | 69 (25.0) | 27 (25.0) | 32 (29.6) | 37 (35.6) | 23 (22.1) | 16 (25.0) | 14 (21.9) | |||
Right half | 54 (19.6) | 73 (26.4) | 22 (20.4) | 27 (25.0) | 16 (15.4) | 28 (26.9) | 16 (25.0) | 18 (28.1) | |||
Clinically significant lesions, n (%) | |||||||||||
Left half | 50 (28.1) | 45 (25.3) | 15 (21.1) | 21 (29.6) | 25 (37.9) | 15 (22.7) | 10 (24.4) | 9 (22.0) | |||
Right half | 34 (19.1) | 49 (27.5) | 13 (18.3) | 22 (31.0) | 7 (10.6) | 19 (28.8) | 14 (34.1) | 8 (19.5) |
PV, prostate volume.
In the vertical direction, there were 151 lesions with single positive slides, including 72 clinically significant lesions. The distribution is shown in Figure 3. The number of lesions with single positive slides in the superior and inferior halves of the prostate was 63 (41.7%) and 111 (73.5%), respectively (P<0.001). The numbers of clinically significant cancer lesions in the superior and inferior halves of the prostate were 32 (45.7%) and 52 (72.2%), respectively (P=0.001). The number of lesions with a single positive slide above the apex 0.5–1.4 cm was 75 (49.7%). The number of clinically significant lesions with a single positive slide above the apex 0.5–1.4 cm was 40 (55.6%).
Concerning the categorization based on different PVs, the apex above 0.5–0.8 cm exhibited the highest positive rate of vertical single positive slides in the groups with 15≤ PV <30 mL and 30≤ PV <45 mL for both all lesions (21.4% and 21.0%, respectively) and clinically significant lesions. In the group with PV ≥45 mL, the apex above 1.1–1.4 cm demonstrated the highest positive rate of vertical single positive slides for both all lesions (21.2%) and clinically significant lesions (25.0%).
The invasion of prostate cancer lesions
The median maximum anteroposterior, left-right, and horizontal diameters of the 335 lesions were 4.0 mm (IQR, 2–10.9 mm), 4.4 mm (IQR, 2–12.1 mm), and 5.4 mm (IQR, 2.4–14.4 mm), respectively. The maximum left-right diameter was longer than the maximum anteroposterior diameter (P=0.046), and the maximum horizontal diameter was longer than the maximum anteroposterior diameter (P<0.001) and left-right diameter (P=0.040). The median of the maximum vertical diameter of all lesions was 6.0 mm (IQR, 2.8–15.5 mm), which was longer than the maximum anteroposterior diameter (P<0.001) and the left-right diameter (P=0.005). No significant difference was found when compared with the maximum vertical and horizontal diameters (P=0.421). The results showed that the invasive tendency of prostate cancer was consistent in the horizontal and vertical dimensions but less consistent in the anteroposterior direction.
In the vertical direction, the distribution of the lesions with a single positive slide, the centers of the lesions, and the positive rates of the lesions in vertical slides are shown in Table 3. There was no significant difference in the vertical distribution between the 151 lesions with a single positive slide and the centers of the 335 lesions. For the centers of the 335 lesions, the positive rate of 0.5–1.1 cm above the apex was the highest (36.4%), which was significantly higher than that of the adjacent slides (P<0.001). For the positive rates of lesions in vertical slides, there was no significant difference between the part 0.5–1.1 cm above the apex and the adjacent layers. The results showed that more than 1/3 of the lesions originated from 0.5–1.1 cm above the apex. With the increased volume of these lesions, they invaded the inferior and superior sides.
Table 3
Variables | Lesions with a single positive slide, % (n/N) | P1 | Centres of lesions, % (n/N) | P2 | Positive rates of lesions of all lesions, % (n/N) | P3 | P4 |
---|---|---|---|---|---|---|---|
Slide 1 | 7.9 (12/151) | – | 10.4 (35/335) | – | 38.8 (130/335) | – | 0.388 |
Slide 2 | 17.2 (26/151) | 0.015 | 20.9 (70/335) | <0.001 | 46.3 (155/335) | 0.051 | 0.346 |
Slide 3 | 12.6 (19/151) | 0.258 | 15.5 (52/335) | 0.072 | 45.3 (151/333) | 0.811 | 0.396 |
Slide 4 | 12.6 (19/151) | >0.99 | 12.2 (41/335) | 0.219 | 43.5 (117/269) | 0.650 | 0.915 |
Slide 5 | 7.3 (11/151) | 0.124 | 4.5 (15/335) | <0.001 | 40.0 (46/115) | 0.526 | 0.203 |
Slide 6 | 15.2 (23/151) | 0.029 | 13.7 (46/335) | <0.001 | 40.9 (137/335) | 0.866 | 0.661 |
Slide 7 | 3.3 (5/151) | <0.001 | 3.0 (10/335) | <0.001 | 21.7 (25/115) | <0.001 | 0.847 |
Slide 8 | 6.6 (10/151) | 0.185 | 6.3 (21/335) | 0.043 | 23.4 (63/269) | 0.720 | 0.883 |
Slide 9 | 7.3 (11/151) | 0.821 | 6.9 (23/335) | 0.755 | 22.8 (76/333) | 0.863 | 0.867 |
Slide 10 | 7.9 (12/151) | 0.828 | 4.8 (16/335) | 0.248 | 17.3 (58/335) | 0.075 | 0.165 |
Slide 11 | 1.3 (2/151) | 0.006 | 1.8 (6/335) | 0.03 | 10.7 (36/335) | 0.014 | 0.708 |
Slide 1 = the apex; Slide 2 = the apex above 0.5–0.8 (excluding 0.5) cm; Slide 3 = the apex above 0.8–1.1 (excluding 0.8) cm; Slide 4 = the apex above 1.1–1.4 (excluding 1.1) cm; Slide 5 = the apex above 1.4–1.7 (excluding 1.4) cm; Slide 6 = the middle slide; Slide 7 = the base below 2.0–2.3 (excluding 2.0) cm; Slide 8 = the base below 1.7–2.0 (excluding 1.7) cm; Slide 9 = the base below 1.3–1.7 (excluding 1.3) cm;
Slide 10 = the base below 1.0–1.3 (excluding 1.0) cm; Slide 11 = the base. P1 was the comparison between the positive rates of two adjacent slides in lesions with a single positive slide; P2 was the comparison between the positive rates of adjacent slides in centres of lesions; P3 was the comparison between the positive rates of adjacent slides in all lesions; P4 was the comparison between the positive rates of lesions with a single positive slide and centres of lesions; “n” represents the number of positive lesions in the corresponding slide; “N” represents the number of specimens having the corresponding slide. As the volume of the prostate organ varies, the number of vertical slices would be different.
Regarding the spatial morphology, the number of lesions with a tumor area that decreased from the center to both sides was 85 (46.2%), and the median volume of these lesions was 1.103 mL (IQR, 0.355–3.138 mL). The number of lesions with a tumor area that decreased from the center to one side was 81 (44.0%), and the median volume of these lesions was 0.098 mL (IQR, 0.031–0.614 mL). Overall, 90.2% of the lesions with tumor areas decreased from the center to both sides or one side. The median volume of the remaining 18 (9.8%) lesions that developed irregularly from the center to both sides was 0.676 mL (IQR, 0.283–1.676 mL).
Discussion
Analyzing the characteristics of prostate cancer on pathomorphology can build a bridge to further study the occurrence and development of prostate cancer from the perspective of molecular biology. At present, research on the origin of prostate cancer is mainly based on the zonal structures, analyzing the prostate’s anatomical structure and gland distribution to determine the origin, distribution, and characteristics of lesions (6,13,14). These results show that most prostate cancer originates from the peripheral zone, and a few originate from the transitional and central zones. The research methods on the origin of prostate cancer in the vertical dimension are based on the results of the specimen being sectioned into slides. The specimen is usually divided into the apex, the base, and the middle part with different slides. Overall, few studies have focused on this subject, and the original information about prostate cancer is insufficient due to the small number of slides taken from the middle part (15). In our study, we took the urethra as the boundary to study the origin of lesions in four horizontal quadrants. This anatomical division can provide more intuitive guidance for transperineal prostate biopsy guided by B-ultrasound. Zonal selection and improving the positive rate on anterior and apical sampling have been the main concerns of prostate biopsy in recent years (16-18). Our study showed that prostate cancer had the same chance of origin in the four horizontal quadrants. Therefore, equal sampling in the four horizontal quadrants through transperineal biopsy can be suggested. In the vertical direction, we divided the prostate into the apex, the base, and various middle slides with a thickness of approximately 3 mm by adopting the standard whole organ sampling procedure. The number of slides taken from the middle part was inconsistent among the different specimens. We selected 11 slides that was present in more than 50% of the specimens. In this way, not only can the sample size of each slice be guaranteed, but also the number of layers can be included as much as possible so that the positive rate between the slices can be comparable and the original information of the prostate would be more sufficient.
Currently, research on autopsy specimens mainly focuses on prostate cancer’s epidemiological and pathological characteristics (19-22). Few studies have used autopsy specimens to analyze the origin of prostate cancer. In Breslow et al.’s study, 350 prostate cancer lesions were divided into large, medium, and small lesions. For small lesions, there was no difference in the distribution in the anterior and posterior zones divided by the urethra. Most small lesions originated from the peripheral zone, and with the increase in tumor volume, the lesions tended to spread inward. Vertically, this study divided the prostate into 4–6 slides according to the size of the prostate. The results showed that the second and third slides above the apex had the highest positive rate (15). However, the number of slices included in this study was relatively small, which would inevitably lead to the missing of some information for the whole prostate organ. Inaba et al. studied the distribution of unsuspected lesions in the peripheral and transitional zones and revealed the characteristics of these lesions in cystoprostatectomy specimens (6). Currently, research on radical prostatectomy specimens for analyzing the origin of prostate cancer is mainly based on the peripheral, transitional, and central zones (23,24). Most studies used autopsy or clinical specimens as independent research objects, while we selected autopsy specimens and low- and medium-risk clinical specimens for the combined study. For autopsy specimens, the tumor volume is often small, which can be better used to analyze the spatial origin of prostate cancer. As there is difficulty in obtaining autopsy specimens and the cost of specimen processing is relatively high, the research sample size will not be too large. Clinical specimens with relatively small tumor volumes can well supplement these shortcomings of autopsy specimens. The tumor volume of prostate cancer in clinical specimens is often larger than that of autopsy specimens, so they can be combined to analyze the tendency of lesions from origin to invasion. These are the reasons and advantages for us to mix the autopsy and clinical specimens for analysis.
In our study, we further selected specimens with tumor volumes equal to or less than one-third of the PV to better analyze the invasion tendency of prostate cancer. Aiming to study the origin and invasion of prostate cancer, the included specimens should have a small tumor volume rather than specimens with a low Gleason score or low T stage. Horizontally, we selected lesions limited to the quarter quadrant and determined their original site in these four quadrants. Vertically, we creatively adopted the concept of a single positive slide and center of the lesion. The origin of lesions in the vertical direction was determined by analyzing the distribution of lesions with a single positive slide. The comparison between the distribution of centers of lesions and lesions with a single positive slide was used to demonstrate the credibility of the concept of the center of the lesion. In our study, there was no significant difference between the distribution of centers of lesions and lesions with a single positive slide. We further compared the distribution of lesions with single positive slides, centers of lesions, and positive rates of lesions in vertical slides to analyze the invasive direction of lesions with increasing tumor volume. The results of our study indicated that lesions originating from 0.5–1.1 cm above the apex invaded both the inferior and superior sides with increasing tumor volume. Clinically significant lesions play a vital role in the diagnosis and treatment of prostate cancer (25,26). For lesions with a single positive slide, the distribution of clinically significant lesions and all lesions were basically consistent. Our investigation into the correlation between the origin of lesions and PV revealed that, within the group with 30≤ PV <45 mL from the anterior zone, there was statistically significant increase in tumor positive rate in the left half compared to the right half. We propose that this observation can be ascribed to the irregular volume of the transitional zone on each side of the prostate in the initial stages of hyperplasia, or the relatively small overall sample size in our study. Additionally, our research suggests that, as the PV surpasses a specific threshold, the primary location of prostate cancer initiation—mainly concentrated in the vertical direction—tends to shift upward.
Without a false envelope, prostate cancer’s spatial morphology is generally considered irregular. However, our study explored the invasive tendency of prostate cancer, including the maximum left-right, anteroposterior diameter and horizontal and vertical diameters. The results showed no significant difference between the maximum vertical and horizontal diameters. In the horizontal direction, prostate cancer developed less in the anteroposterior direction. However, since the P value was close to 0.05, the conclusion needs to be further verified with a larger sample size. In addition, our research showed that 90.2% of lesions with tumor areas decreased from the center to both sides or one side. The results further indicate that the center of the lesion can be used as a convincing and recommended concept for describing the morphology of prostate cancer.
This study has some shortcomings. On the one hand, this is a single-center study and may be accompanied by some biases in the selection of the clinical and autopsy specimens. On the other hand, the analysis of the origin and invasion of lesions is limited to the field of pathomorphology. However, it is necessary to carry out a genomic analysis to truly determine the origin of these lesions. Moreover, considering the clonal evolution and heterogeneity of prostate cancer, the occurrence and development of prostate cancer seem more complex at the molecular biological level (27,28). This also points out the direction for our future work. Ultimately, the basic information of our included patients lacks details regarding the treatment of benign prostatic hyperplasia with 5-alpha reductase inhibitors, such as finasteride. These medications selectively constrict the prostate transition zone, potentially creating more room in the peripheral zone and influencing the outcomes related to lesion origin and progression.
Conclusions
In our study, the origin of prostate cancer was consistent in four horizontal quadrants. Approximately 50% of the lesions originate from the apex above 0.5–1.4 cm. The invasive tendency of prostate cancer was consistent in the horizontal and vertical dimensions but less so in the anteroposterior direction. About ninety percent of lesions with tumor area decreased from the center to both sides or one side.
Acknowledgments
Funding: This study was supported by
Footnote
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