Baseline total metabolic tumor volume combined with international peripheral T-cell lymphoma project may improve prognostic stratification for patients with peripheral T-cell lymphoma (PTCL)

Patients recently diagnosed with PTCL (including PTCL-NOS, AITL, ALCL ALK negative) who underwent pretreatment whole-body ¹⁸F-FDG PET/CT between March 2009 and January 2019 were enrolled in this retrospective study. To be included, patients were required to be treated with CHOP, a CHOP-like regimen or dose-adjusted etoposide, prednisone, vincristine, cyclophosphamide and doxorubicin (DA-EPOCH) regimens with a curative intent and had to be free of any concurrent diseases that precluded the protocol treatment. Patients were excluded if they had a previous malignancy, chemotherapy, radiotherapy, pregnancy (lactation), or diabetes mellitus with a fasting blood glucose level greater than 150 mg/dL. In addition, ALCL patients with ALK positivity who had a different treatment (ALK inhibitor therapy), and those with relatively favorable prognosis were excluded. Clinical parameters (sex, age, B symptoms, ECOG PS, Ann Arbor Stage, LDH level, platelet count, bone marrow biopsy [BMB] results and Ki-67) were determined from the medical records. Approval was obtained from the Ethics Committee of Nanjing Drum Tower Hospital, the Affiliated Hospital of Nanjing University Medical School. All of the subjects signed a written consent form.

According to the criterion previously described [4, 5, 9], the three score systems (IPI, PIT and IPTCLP) were calculated. The IPI includes five variables: age (≤ 60 vs > 60), performance status ECOG (≤ 1 vs > 2), LDH level (low vs high), Ann Arbor stage (I–II vs III–IV) and extranodal involvement (≤ 1 vs > 2). Four risk groups were defined by IPI: score 0–1, low risk; score 2, low-intermediate risk; score 3, high-intermediate risk and score 4–5, high risk, respectively. The PIT includes 4 variables: age (≤ 60 vs > 60), performance status (ECOG ≤ 1 vs > 2), LDH level (low vs high) and BM involvement (negative versus positive). Four risk groups were defined by PIT: score 0, low risk; score 1, low-intermediate risk; score 2, high-intermediate risk and score ≥ 3, high risk, respectively. The IPTCLP includes 3 variables: age (≤ 60 vs > 60), ECOG performance status (ECOG PS ≤ 1 vs > 2) and platelet cell count (< 150 × 10⁹/l vs ≥ 150 × 10⁹/L). Four risk groups were defined by IPTCLP: score 0, low risk; score 1, low-intermediate risk; score 2, high-intermediate risk and score 3, high risk, respectively. For the purpose of this study, the four risk groups were dichotomized into low-risk IPI, PIT and IPTCLP (comprising low- and low-intermediate-risk patients) and high-risk (comprising high-intermediate- and high-risk patients) groups.

All of the patients underwent whole-body ¹⁸F-FDG PET/CT on a combined Gemini GXL PET/CT scanner with a 16-slice CT component (Philips Corp, Netherlands). After 6 h of fasting (no oral or intravenous fluids containing sugar or dextrose), 185–370 MBq of ¹⁸F-FDG (5.18 MBq/kg) was administered intravenously. Each patient’s blood glucose level was checked immediately before ¹⁸F-FDG administration. Each patient was weighed for determination of the standardized uptake value (SUV) prior to each scan. Whole-body PET/CT scans (from the base of the skull to the upper thigh) were started 60 min following radiopharmaceutical injection. Emission data were acquired for 2 min in each bed position. CT acquisition data were used for attenuation correction, and corrected PET images were reconstructed using ordered-subset expectation maximization (OSEM). The matrix size is 144 × 144. The acquired images from the PET and CT scans were sent for image registration and fusion using Syntegra software.

PET/CT images were read by two physicians specializing in nuclear medicine. These physicians were blind to any patient information or to any of the patient's clinical conditions. When in doubt, the results were determined by a consensus between the two physicians. Images were reviewed using volume-viewer software on a dedicated workstation (Compassview 5.0, Philips Corp, the Netherlands) to calculate SUV and MTV. Regions of interest (ROIs) were placed manually to cover the lesion, and the maximum SUV (SUVmax) value was recorded for each lesion. For each PET dataset, the SUVmax was defined as the highest SUV among all of the hypermetabolic tumor foci. MTV was determined by drawing a circular ROI fully encasing all involved lesions in axial, coronal, and sagittal PET/CT images. Then, the boundaries of voxels were produced automatically with the 41% SUVmax threshold method recommended by the European Association of Nuclear Medicine [10]. Normal organs and false-positive lesions—such as inflammation, infection or other benign FDG-avid lesions based on histopathological reports or other imaging modalities—were subtracted. The TMTV was obtained by summing the MTV of all lesions. TLG was calculated as the sum of all MTV × SUV (mean of lesions) in each patient. SUVmax values were obtained and corrected for body weight using the following standard formula: mean ROI activity (MBq/mL)/[injected dose (MBq)/body weight (kg)].

Eighty-four patients (30 women and 54 men), including 47 patients with PTCL-NOS, 30 with AITL, and 7 with ALCL (ALK negative), were included in this study. Their clinical characteristics are summarized in Tables 1 and 2. The median patient age was 62 years (range 16–85 years). The average SUVmax, TMTV and TLG of the primary tumors were 11.2 (2.6–33.5), 347.3 (3.4–1687.0) cm³ and 1043.3 (10.9–6308.0), respectively. After a median follow-up of 20.0 months (range 4–131 months), 47 patients had disease relapse or progression, and 46 patients died.

In the present study, ROC curve analysis was used to calculate the accuracy of ideal cut-off values to distinguish a low SUVmax group from a high SUVmax group, a low TMTV group from a high TMTV group and a low TLG group from a high TLG group. The estimated area under the ROC curve (AUROC) for SUVmax was 0.617, that for TMTV was 0.797 and that for TLG was 0.696. The ideal cut-off values for SUVmax, TMTV and TLG were 6.9, 228.8 cm³ and 437.3, respectively. The sensitivity, specificity, accuracy, positive predictive value and negative predictive value in predicting PFS and OS are listed in Table 3.

Table 4 shows the differences in clinical characteristics between the dichotomized TMTV and TLG groups. Patients with high TMTV and TLG usually possessed the following characteristics: high IPI and PIT scores. In addition, the results showed that the B symptoms and ECOG PS were significantly associated with TMTV, and LDH level was significantly associated with TLG.

The mean PFS was 55.0 mo (95% CI: 41.1–68.9 months, range: 4–79 months), and the mean OS was 57.4 months (95% CI 43.5–71.2 months, range 4–71 months). The PFS and OS estimates for all of the patients were 44.0% and 45.2%, respectively. Univariate analysis showed that B symptoms, BMB positive result, a high LDH level, high ECOG PS, high platelet cell count, high IPI score, high PIT score, high IPTCLP score, high SUVmax, high TMTV and high TLG were significantly correlated with inferior PFS and OS. The survival curves and univariate analyses are shown in Fig. 1 and Table 5. TMTV and IPTCLP were independent predictors of both PFS [HR (95% CI): 5.096 (2.579–10.072), P < 0.001; HR (95% CI): 2.577 (1.405–4.727), P = 0.002] and OS [HR (95% CI): 4.647 (2.361–9.148), P < 0.001; HR (95% CI): 2.360 (1.285–4.336), P = 0.006] after multivariate analysis (Table 6).

The baseline TMTV was added to the IPTCLP score systems, and patients were divided into three risk groups with significantly different PFS (χ² = 39.795, P < 0.001) and OS (χ² = 35.871, P < 0.001) values. (Fig. 2). In a subanalysis, the high-risk group (TMTV > 228.8 cm³ and IPTCLP score of 2, 3) had relatively lower survival than those in the low-risk group (TMTV ≤ 228.8 cm³ and IPTCLP score of 0–1) and intermediate-risk group (TMTV > 228.8 cm³ or IPTCLP score of 2, 3) (PFS: χ² = 42.120, P < 0.001; χ² = 13.322, P < 0.001; OS: χ² = 36.056, P < 0.001; χ² = 10.883, P = 0.001). In addition, the intermediate-risk group (TMTV > 228.8 cm³ and IPTCLP score of 2, 3) also had relatively lower survival than those in the low-risk group (TMTV ≤ 228.8 cm³ and IPTCLP score of 0–1) (PFS: χ² = 12.512, P < 0.001; OS: χ² = 12.262, P < 0.001). Outcomes according to the combination of TMTV and the IPTCLP are listed in Table 7.