Recurrent Disease in Patients With Sporadic Pheochromocytoma and Paraganglioma

Supplemental Appendix for manuscript 'Recurrent disease in patients with sporadic pheochromocytoma and paraganglioma

PRAP study - partial versus radical adrenalectomy in hereditary pheochromocytomas

Objective: Hereditary pheochromocytoma (hPCC) commonly develops bilaterally, causing adrenal insufficiency when standard treatment, radical adrenalectomy (RA), is performed. Partial adrenalectomy (PA) aims to preserve adrenal function, but with higher recurrence rates. This study compares outcomes of PA versus RA in hPCC. Methods: Patients with hPCC due to pathogenic variants in RET, VHL, NF1, MAX, and TMEM127 from 12 European centers (1974-2023) were studied retrospectively. Stratified analysis based on surgery type and initial presentation was conducted. The main outcomes included recurrence, adrenal insufficiency, metastasis, and mortality. Results: The study included 256 patients (223 RA, 33 PA). Ipsilateral recurrence rates were 9/223 (4%) after RA versus 5/33 (15%) after PA (P = 0.02). Metastasis and mortality did not differ between groups. Overall, 103 patients (40%) underwent bilateral adrenalectomy either synchronously or metachronously (75 RA, 28 PA). Of these, 46% developed adrenal insufficiency after PA. In total, 191 patients presented with initial unilateral disease, of whom 50 (26%) developed metachronous contralateral disease, most commonly in RET, VHL, and MAX. In patients with metachronous bilateral disease, adrenal insufficiency developed in 3/4 (75%) when PA was performed as the first operation followed by RA, compared to 1/7 (14%) when PA was performed as the second operation after prior RA (P = 0.09). Conclusion: In patients with hPCC undergoing PA, local recurrence rates are higher than after RA, but metastasis and disease-specific mortality are similar. Therefore, PA seems a safe method to preserve adrenal function in patients with hPCC, in cases of both synchronous and metachronous bilateral disease, when performed as a second operation.</p

A comparison of high‑throughput plasma NMR protocols for comparative untargeted metabolomics (Metabolomics

Following publication of the original article, the authors would like to correct a sentence in the paragraph “1H-NMR spectra were recorded at 298 K…” under the heading “NMR experiments”. The sentence currently reads: “The LED pulse sequence had the form -RD-901-G1- 1801-G1-901-G2-T-901-G1-1801-G1-901-G2-t-901-acquire FID, where RD is a relaxation delay, 901 is a 901 RF pulse, G1 is the pulsed-field gradient that is applied to allow editing, 1801 is a 1801 RF pulse, G2 is a spoil gradient applied to remove unwanted magnetization components. The diffusion delay Δ is the time during which the molecules are allowed to diffuse—this is the period (901-G1-1801-G1- 901-G2-T-); and t is a delay to allow the longitudinal eddy currents caused within the sample to decay (Beckonert et al. 2007).” The sentence should read: “The LED pulse sequence had the form -RD-90°-G1- 180°-G1-90°-G2-T-90°-G1-180°-G1-90°-G2-t-90°-acquire FID, where RD is a relaxation delay, 90° is a 90° RF pulse, G1 is the pulsed-field gradient that is applied to allow editing, 180° is a 180° RF pulse, G2 is a spoil gradient applied to remove unwanted magnetization components. The diffusion delay ? is the time during which the molecules are allowed to diffuse—this is the period (90°-G1-180°-G1-90°-G2 T-); and t is a delay to allow the longitudinal eddy currents caused within the sample to decay (Beckonert et al. 2007).” This has been corrected with this erratum.</p

Metabolic subtyping of pheochromocytoma and paraganglioma by 18F-FDG pharmacokinetics using dynamic PET/CT scanning

Static single–time-frame 18F-FDG PET/CT is useful for the localization and functional characterization of pheochromocytomas and paragangliomas (PPGLs). 18F-FDG uptake varies between PPGLs with different genotypes, and the highest SUVs are observed in cases of succinate dehydrogenase (SDH) mutations, possibly related to enhanced aerobic glycolysis in tumor cells. The exact determinants of 18F-FDG accumulation in PPGLs are unknown. We performed dynamic PET/CT scanning to assess whether in vivo 18F-FDG pharmacokinetics has added value over static PET to distinguish different genotypes. Methods: Dynamic 18F-FDG PET/CT was performed on 13 sporadic PPGLs and 13 PPGLs from 11 patients with mutations in SDH complex subunits B and D, von Hippel-Lindau (VHL), RET, and neurofibromin 1 (NF1). Pharmacokinetic analysis was performed using a 2-tissue-compartment tracer kinetic model. The derived transfer rate-constants for transmembranous glucose flux (K1 [in], k2 [out]) and intracellular phosphorylation (k3), along with the vascular blood fraction (Vb), were analyzed using nonlinear regression analysis. Glucose metabolic rate (MRglc) was calculated using Patlak linear regression analysis. The SUVmax of the lesions was determined on additional static PET/CT images. Results: Both MRglc and SUVmax were significantly higher for hereditary cluster 1 (SDHx, VHL) tumors than for hereditary cluster 2 (RET, NF1) and sporadic tumors (P, 0.01 and P, 0.05, respectively). Median k3 was significantly higher for cluster 1 than for sporadic tumors (P, 0.01). Median Vb was significantly higher for cluster 1 than for cluster 2 tumors (P, 0.01). No statistically significant differences in K1 and k2 were found between the groups. Cutoffs for k3 to distinguish between cluster 1 and other tumors were established at 0.015 min−1 (100% sensitivity, 15.8% specificity) and 0.636 min−1 (100% specificity, 85.7% sensitivity). MRglc significantly correlated with SUVmax (P 5 0.001) and k3 (P 5 0.002). Conclusion: In vivo metabolic tumor profiling in patients with PPGL can be achieved by assessing 18F-FDG pharmacokinetics using dynamic PET/CT scanning. Cluster 1 PPGLs can be reliably identified by a high 18F-FDG phosphorylation rate

SDHAF2 (PGL2-SDH5) and hereditary head and neck paraganglioma

Contains fulltext : 97331.pdf (publisher's version ) (Closed access)PURPOSE: Hereditary head and neck paraganglioma (HNPGL) syndromes are associated with mutations in the SDHD(PGL1), SDHC(PGL3), and SDHB(PGL4) genes encoding succinate dehydrogenase subunits. We recently described mutations in a previously uncharacterized human gene, now called SDHAF2, and showed that this was the long-sought "imprinted" PGL2 gene. Here, we present a new branch of the Dutch SDHAF2 (PLG2-SDH5) family. EXPERIMENTAL DESIGN: The SDHAF2 family has been collected over a 30-year period. The family described here was linked to PGL2 and at-risk family members were invited to participate in this study. Patients were investigated and treated dependent on tumor size and localization. All family members have now been analyzed for the SDHAF2 mutation status. RESULTS: Among the 57 family members, 23 were linkage positive including 7 risk-free carriers (maternal imprinting). Of the 16 at-risk individuals, 11 had a total of 24 tumors with primarily carotid (71%) and vagal locations (17%). Multifocality of tumors was prominent (91%). Malignancy was not detected. The average age at onset was 33 years, and many patients (42%) were asymptomatic prior to screening. SDHAF2 mutation analysis confirmed the findings of the previously performed linkage analysis without detection of discrepancies. CONCLUSIONS: We established the SDHAF2 mutation status of PGL2 family members. Phenotypic characterization of this family confirms the currently exclusive association of SDHAF2 mutations with HNPGL. This SDHAF2 family branch shows a young age at onset and very high levels of multifocality. A high percentage of patients were asymptomatic at time of detection

Loss of sdhb in zebrafish larvae recapitulates human paraganglioma characteristics

Pheochromocytomas and paragangliomas (PPGLs) caused by mutations in the B-subunit of the succinate dehydrogenase (SDHB) have the highest metastatic rate among PPGLs, and effective systemic therapy is lacking. To unravel underlying pathogenic mechanisms, and to evaluate therapeutic strategies, suitable in vivo models are needed. The available systemic Sdhb knock-out mice cannot model the human PPGL phenotype: Heterozygous Sdhb mice lack a disease phenotype, and homozygous Sdhb mice are embryonically lethal. Using CRISPR/cas9 technology, we introduced a protein-truncating germline lesion into the zebrafish sdhb gene. Heterozygous sdhb mutants were viable and displayed no obvious morphological or developmental defects. Homozygous sdhb larvae were viable, but exhibited a decreased lifespan. Morphological analysis revealed incompletely or non-inflated swim bladders in homozygous sdhb mutants at day 6. Although no differences in number and ultrastructure of the mitochondria were observed. Clear defects in energy metabolism and swimming behavior were observed in homozygous sdhb mutant larvae. Functional and metabolomic analyses revealed decreased mitochondrial complex 2 activity and significant succinate accumulation in the homozygous sdhb mutant larvae, mimicking the metabolic effects observed in SDHB-associated PPGLs. This is the first study to present a vertebrate animal model that mimics metabolic effects of SDHB-associated PPGLs. This model will be useful in unraveling pathomechanisms behind SDHB-associated PPGLs. We can now study the metabolic effects of sdhb disruption during different developmental stages and develop screening assays to identify novel therapeutic targets in vivo. Besides oncological syndromes, our model might also be useful for pediatric mitochondrial disease caused by loss of the SDHB gene

The influence of the exclusion of central necrosis on [¹⁸F]FDG PET radiomic analysis

Background: Central necrosis can be detected on [18F]FDG PET/CT as a region with little to no tracer uptake. Currently, there is no consensus regarding the inclusion of regions of central necrosis during volume of interest (VOI) delineation for radiomic analysis. The aim of this study was to assess how central necrosis affects radiomic analysis in PET. Methods: Forty-three patients, either with non-small cell lung carcinomas (NSCLC, n = 12) or with pheochromocytomas or paragangliomas (PPGL, n = 31), were included retrospectively. VOIs were delineated with and without central necrosis. From all VOIs, 105 radiomic features were extracted. Differences in radiomic features between delineation methods were assessed using a paired t-test with Benjamini-Hochberg multiple testing correction. In the PPGL cohort, performances of the radiomic models to predict the noradrenergic biochemical profile were assessed by comparing the areas under the receiver operating characteristic curve (AUC) for both delineation methods. Results: At least 65% of the features showed significant differences between VOIvital-tumour and VOIgross-tumour (65%, 79% and 82% for the NSCLC, PPGL and combined cohort, respectively). The AUCs of the radiomic models were not significantly different between delineation methods. Conclusion: In both tumour types, almost two-third of the features were affected, demonstrating that the impact of whether or not to include central necrosis in the VOI on the radiomic feature values is significant. Nevertheless, predictive performances of both delineation methods were comparable. We recommend that radiomic studies should report whether or not central necrosis was included during delineation.Biomechanical Engineerin

Circulating adrenomedullin and B-type natriuretic peptide do not predict blood pressure fluctuations during pheochromocytoma resection: A cross-sectional study

Background: Despite adequate presurgical management, blood pressure fluctua tions are common during resection of pheochromocytoma or sympathetic paraganglioma (PPGL). To a larg e extent, the variability in blood pressure control during PPGL resection remains unexplained. Adrenomedullin and B -type natriuretic peptide, measured as MR-proADM and NT-proBNP, respectively, are circulating biomarkers of card iovascular dysfunction. We investigated whether plasma levels of MR-proADM and NT-proBNP are associated with bl ood pressure fluctuations during PPGL resection. Methods: Study subjects participated in PRESCRIPT, a randomized control led trial in patients undergoing PPGL resection. MR-proADM and NT-proBNP were determined in a single plasma sample drawn before surgery. Multivariable linear and logistic regression analyses were used to explore associations between these biomarkers and blood pressure fluctuations, use of vasoconstrictive agents duri ng surgery as well as the occurrence of perioperative cardiovascular events. Results: A total of 126 PPGL patients were included. Median plasma conc entrations of MR-proADM and NT-proBNP were 0.51 (0.41-0.63) nmol/L and 68.7 (27.9-150.4) ng/L, respec tively. Neither MR-proADM nor NT-proBNP were associated with blood pressure fluctuations. There was a positiv e correlation between MR-proADM concentration and the cumulative dose of vasoconstrictive agents (03B2 0.44, P = 0.001). Both MR-proADM and NT-proBNP were significantly associated with perioperative cardiovascular events (OR: 5.46, P = 0.013 and OR: 1.54, P = 0.017, respectively). Conclusions: Plasma MR-proADM or NT-proBNP should not be considered as biom arkers for the presurgical risk assessment of blood pressure fluctuations during PPGL resection. Future studies are needed to explore the potential influence of these biomarkers on the intraoperative requirement of vasoconstrictive agents and the perioperative cardiovascular risk