Diffuse peritoneal mesothelioma (DPM) is a rare and highly aggressive primary tumor, characterized by its invasive nature, frequent misdiagnosis and poor prognosis (1–3). DPM accounts for 7–30% of all mesothelioma cases, with marked geographic variation in incidence. In the USA, ~15,000 new cases are reported annually, while in China, the incidence increased from 2.14 to 3.14 per 106 between 2000 and 2013 (4,5). The etiology of DPM is primarily associated with asbestos exposure; however, only 33–50% of patients have a clear history of exposure. Other contributing factors include physicochemical carcinogens, chronic peritonitis, and genetic susceptibility, such as BRCA1-associated protein 1 (BAP1) mutations (6,7). As asbestos has not been completely banned in China, the incidence of DPM may continue to increase in the future.

Most DPM is asymptomatic or non-specific in the early stages, with insidious onset, and is diagnosed in the mid- to late-stage, with a median time from symptom onset to diagnosis of ~4 months (8,9). The diversity of clinical manifestations depends largely on the extent of tumor spread in the abdominal cavity. The main clinical manifestations include abdominal distension (41–86%) and abdominal pain (31–87%), and may also include weight loss, abdominal masses, and, in some cases, paraneoplastic syndromes. A definitive diagnosis of DPM requires a histopathological examination. DPM etiology and pathogenesis remain to be fully elucidated and current management involves cytoreductive surgery (CRS) combined with hyperthermic intraperitoneal chemotherapy (HIPEC) and systemic chemotherapy. Patients treated with this therapy have improved 5-year overall survival and progression-free survival (PFS) rates compared with untreated patients (10–12). The present study reports a case of DPM misdiagnosed as mesenteric panniculitis, detailing its clinical course, highlighting the diagnostic challenges, presenting the management outcomes and discussing the potential association with occupational asphalt exposure.

To the best of our knowledge, the present case is the first reported instance worldwide of a road maintenance worker with long-term exposure to asphalt who developed DPM and was misdiagnosed with mesenteric panniculitis. A previous study reported the misdiagnosis of DPM as ovarian cancer or abdominal tuberculosis (3). To the best of our knowledge, the present case is the first to define the characteristic imaging evolution over 18 months during which diffuse peritoneal mesothelioma was initially misdiagnosed as mesenteric panniculitis (presenting as mild omental thickening and minimal effusion) and demonstrated typical features of DPM including diffuse omental thickening, intra-abdominal masses, and cardiophrenic angle lymph node metastasis. This progression gives imaging indications for the early clinical differentiation between the two conditions. A rare calretinin-negative immunophenotype of epithelioid DPM was identified, which accounts for 8.7% of epithelioid DPM cases (12). A triple-marker panel of WT-1, HBME-1 and D2-40 was used to avoid misconceptions based on calretinin-only testing and to refine the DPM immunohistochemical diagnostic system. Clinical evidence for the non-surgical treatment of patients with DPM with a high PCI score (27 points) who refuse surgery is provided in the study. Pemetrexed + cisplatin chemotherapy achieved a 55% decrease in the sum of the longest diameters of peritoneal masses (from 6.0 to 2.7 cm), as calculated per RECIST 1.1 criteria (15), representing tumor regression although standard doses were associated with grade III myelosuppression. A dose adjustment regimen of 600–700 mg/m² was proposed, filling the clinical gap of a lack of standardized treatment protocols for patients with diffuse peritoneal mesothelioma, PCI >15), and who refuse cytoreductive surgery.

A potential association between asphalt exposure and DPM was identified. An epidemiological meta-analysis by Partanen and Boffetta (19) reported a 2.3-fold increased risk of developing malignant tumors in the abdominal cavity among individuals exposed to asphalt and showed a dose-response relationship. The present patient had a 28-year history of unprotected exposure to asphalt, constituting high-risk exposure. Asphalt contains carcinogens, such as polycyclic aromatic hydrocarbons (PAHs) and benzo(a)pyrene, which cause DNA damage in peritoneal mesothelial cells by generating reactive oxygen species, a similar mechanism to that of asbestos (20). A global population study by Jin et al (21) showed that DPM incidence did not decrease markedly following the ban or restriction of asbestos, suggesting a potential role for non-asbestos carcinogens. The present case gives the first clinical evidence to support this conclusion.

Asbestos exposure is associated with DPM, although with a weaker association than for the more common pleural mesothelioma (17,21). The length of asbestos fibers, which may exceed the capacity for phagocytosis, causing release of reactive oxygen species (ROS) and an inflammatory and mutagenic environment, seems a likely explanation for mesothelioma occurrence at both the pleural and peritoneal sites (20,22). Less is known about the impact of genetic susceptibility at the two sites, although some predisposing polymorphisms in genes including BAP1, TP53, GSTT1 and XRCC1 have been linked to the pleural form of the disease (23). DPM is characterized by extensive proliferation along peritoneal surfaces, often adhering to organs. Typical radiological findings include diffuse peritoneal and omental thickening, abdominal masses, ascites and lymph node metastases (24).

The present patient had no history of asbestos exposure but had long been engaged in highway maintenance work. The base asphalt + modifier products commonly used in highway maintenance do not contain natural asbestos but, when heated to 160–180°C, they release PAHs, benzo(a)pyrene and volatile organic compounds. The asphalt aggregate contains additional heavy metal impurities, such as chromium and nickel, which are classified as Group 1 or Group 2A carcinogens by the International Agency for Research on Cancer (25). Asphalt carcinogens induce malignant transformation of peritoneal mesothelial cells through two pathways (20,26). First, PAHs are metabolized by cytochrome P450 to produce ROS, causing point mutations in tumor suppressor genes, such as p53 and CDKN2A, which disrupt cell cycle regulation. Second, long-term accumulation of asphalt microparticles and heavy metals in the peritoneal cavity may trigger chronic aseptic inflammation, activate the NF-κB pathway and create a tumor-promoting microenvironment, leading to abnormal proliferation and invasion of mesothelial cells. Occupational exposure to potential carcinogens, such as asphalt, may have occurred in the present case (19,21,27) and contributed to the disease. However, causal evidence is lacking and further epidemiological and mechanistic studies are needed to validate the association. Mesothelioma may involve the pleura, peritoneum and pericardium with pleural mesothelioma being the most common (accounting for 80–85%), followed by peritoneal mesothelioma (15%) and pericardial mesothelioma being rare (<1%) (21,28). The present case involved peritoneal involvement without manifestations of pleural or pericardial involvement (chest CT showed no pleural thickening or pericardial effusion), consistent with the typical site characteristics of DPM.

An accurate diagnosis of DPM relies on histopathological examination, including morphological observation of biopsy specimens and immunohistochemical verification. Tumor cell morphological features, such as a tubular arrangement of epithelioid cells and spindle-shaped morphology of sarcomatoid cells, must be examined microscopically and combined with positivity for at least two mesothelioma-specific markers (such as WT-1, D2-40 and HBME-1) and two negative markers (such as CEA and thyroid transcription factor 1) while excluding metastatic carcinoma or other peritoneal tumors (29,30). The following tests for markers associated with metastatic cancer of gastrointestinal and female reproductive tract origin were performed for the present case with the following results: CK7(−), CK20(−), CDX2(−), p16(−), paired box gene 8 (PAX8)(−), p53 (wild-type, positivity rate <10%), estrogen receptor (ER)(−) and progesterone receptor (PR)(−). Combined with the previous negative results for CEA and MUC family, common malignant tumors with peritoneal metastasis, such as gastrointestinal adenocarcinoma, may be excluded, meeting the core requirement of ‘exclusion of metastatic cancer’ in the 2023 IMIG Mesothelioma Diagnostic Guidelines (29). The annual age-adjusted incidence of secondary peritoneal metastases is 99.00/1,000,000 persons, compared with only 4.36 per 1,000,000 persons for primary peritoneal malignancies including mesothelioma (31). The combination of the aforementioned markers is key to the differential diagnosis, since tumors of gastrointestinal origin are often CK7/CK20/CDX2-positive and tumors of female reproductive tract origin are frequently associated with abnormal expression of PAX8, ER/PR or p16 (30). All of these were negative for the present patient, and the mesothelioma-specific phenotype of WT-1, HBME-1 and D2-40 confirmed the accuracy of the DPM diagnosis. Tumor, lymph node involvement and metastasis staging must factor in the PCI, which evaluates the size and distribution of peritoneal tumors (32). The American Cancer Society has reported that patients have markedly improved prognosis in the earlier stages, with 5-year survival rates being 87% at stage I, 53% at stage II and 29% at stage III (33,34). Laparoscopic biopsy allowed a definitive diagnosis for the present case. A nodular lesion was identified at the site of the laparoscopic port in the right lower quadrant of the abdominal wall at 1 month post-surgery, indicating the occurrence of implantation metastasis. This observation indicates the aggressive nature of this type of tumor and may suggest a particularly poor prognosis for the patient (35).

Standardized treatment protocols have yet to be established for DPM. CRS + HIPEC is recommended by the PSOGI, with the aim of removing visible tumors and separate adhesions to improve HIPEC efficiency (21). This therapeutic strategy carries a notable rate of grade 3–4 complications; however, the 5-year survival rate has been extended to 42% from the baseline of <15% for patients treated with non-CRS + HIPEC regimens (36). Systemic chemotherapy protocols for DPM have their basis in those established for pleural mesothelioma, and pemetrexed in combination with cisplatin, carboplatin or gemcitabine is generally preferred, especially for patients who are not candidates for CRS + HIPEC. Intraperitoneal chemotherapy increases local drug concentrations, giving more efficacious treatment of peritoneal surface malignancies and reducing systemic side effects (37). Promising results were reported for the treatment of 26 patients with unresectable DPM treated with pressurized intraperitoneal aerosol chemotherapy. The treatment achieved clinical symptom improvement in 32% of patients and ascites control in 46%; 54% of patients underwent successful CRS + HIPEC, with a median progression-free survival of 33.5 months in resected patients vs. 7.4 months in unresected patients (38). Although the present patient initially achieved a PR with pemetrexed at a close to standard dose, grade III myelosuppression developed. Therefore, patients with DPM who have a high PCI score and refuse surgery are recommended a dose-adjusted regimen (such as pemetrexed 600–700 mg/m²) to balance efficacy and safety.

No targets suitable for immunotherapy were identified in the present case by genetic testing, rendering immunotherapy inappropriate. The patient received six cycles of chemotherapy with pemetrexed (800 mg on day 1) combined with cisplatin (40 mg on days 1–3). Although a PR was achieved (35% reduction in peritoneal mass; CA125 decreased from 160.6 to 156.5 U/ml), Grade III bone marrow suppression (lowest neutrophil count 0.8×10⁹/l) and grade II gastrointestinal reactions developed. This indicates that while the regimen is effective for low-grade epithelioid DPM, enhanced toxicity management is required (for example, prophylactic use of granulocyte colony-stimulating factor and 5-HT3 receptor antagonists). The reasons for the ineffectiveness of intraperitoneal perfusion therapy could be due to the regimen being adjusted to intraperitoneal cisplatin (30 mg) + bevacizumab (300 mg) at 11 months while disease progression occurred within 1 month. This treatment regimen constitutes off-label compassionate use. The treatment decision was based on two factors. First, the patient's disease progressed after six cycles of pemetrexed plus cisplatin chemotherapy and no standard second-line regimen was available. Second, the anti-angiogenic mechanism of bevacizumab may have a synergistic effect on malignant peritoneal tumors and a small number of studies (39,40) on intraperitoneal administration for ovarian cancer and colorectal cancer with peritoneal metastases have demonstrated a potential for local tumor control (38). The tumor may have extensively invaded extraperitoneal tissues (such as peritoneal wall puncture site metastasis), rendering local drug concentrations insufficient to effectively cover the lesions, and there exists a lack of medical evidence for bevacizumab in the intraperitoneal treatment of DPM (38). This suggests that careful evaluation of the extent of tumor invasion should be made when selecting intraperitoneal perfusion regimens. The present case suggests that patients with DPM with high PCI scores (>15) who refuse surgery should have initial chemotherapy that prioritizes ‘dose-adjusted regimens with manageable toxicity’ (for example, reducing pemetrexed to 600–700 mg/m²) while monitoring tumor markers (CA125 and Cyfra 21–1) and imaging changes to identify disease progression early and adjust treatment strategies.

There were several limitations to the present study. Current international guidelines recommend CRS + HIPEC as the first-line treatment for resectable DPM with patients receiving this regimen achieving a 5-year survival rate of 42% (36). By contrast, the present case received only systemic chemotherapy (pemetrexed + cisplatin) and intraperitoneal perfusion therapy (cisplatin + bevacizumab), falling within the second-line treatment category for ‘unresectable/ surgery refusal’. The treatment efficacy (13-month survival) reflects outcomes only for this patient population and cannot be extrapolated to patients with DPM eligible for CRS + HIPEC. In addition, due to the absence of efficacy data from a CRS + HIPEC treatment group (such as tumor burden reduction and PFS), the outcome in this case of PR to pemetrexed-cisplatin chemotherapy followed by progression does not validate the superiority of ‘non-surgical treatment vs. surgery combined with HIPEC’ and acts as a reference only for patients similarly unable to undergo CRS + HIPEC. There are also ethical review limitations: The intraperitoneal bevacizumab combined with cisplatin regimen has not undergone institutional review board approval. Informed consent was obtained from the patient and their family but strict adherence to ethical review procedures is still required in subsequent clinical practice to ensure the compliance of the treatment regimen. The purulent fluid found in the peritoneal cavity during laparoscopy was not subjected to cytological examination or microbiological culture and the possibility of a concurrent infection cannot be ruled out. The diagnosis of malignancy could not be supported by the cytological analysis of peritoneal fluid, which may have impacted clinical decision-making. The present PCI score of 27 points was determined from combined assessment by laparoscopic examination and radiologists (32). However, laparoscopic PCI assessment has limitations due to incomplete visualization of the abdominal cavity, particularly regarding tumor involvement in hidden areas such as subphrenic and retrohepatic regions, and may lead to underestimation of the true tumor burden (34). By contrast, open surgery allows for complete abdominal exploration and yields a more accurate PCI score (41). Furthermore, there is a lack of high-level (randomized controlled trials, systematic reviews, or meta-analyses) evidence supporting intraperitoneal bevacizumab therapy for DPM, and the lack of response observed in the present case underscores the uncertainty of this treatment regimen (37). The use off-label intraperitoneal cisplatin + bevacizumab was made to inform potential treatment options for patients with advanced disease and may serve as a reference for future studies.

In conclusion, the present study presents a case of DPM initially misdiagnosed as mesenteric panniculitis, illustrating the difficulties of the early diagnosis and treatment of DPM. More effective therapeutic interventions are needed which may be diversified by future developments in immunotherapy and genotyping techniques to inform future treatment strategies for DPM.