Stanislas Pauwels

Gastrinoma (Duodenal and Pancreatic)

a Digestive Diseases Branch, NIH, Bethesda, Md. , USA; b Division of General Surgery, Department of Surgery, Medical University of Vienna, Vienna , Austria; c Department of Hepatology and Gastroenterology, CHV A Pare Hospital, Boulogne , France; d Department of Gastroenterology, North Hampshire Hospital, Hampshire , UK; e Department of Surgery, Vivantes Humboldt Hospital, Berlin , Germany; f Department of Radiology, Royal Marsden Hospital, Sutton , UK; g Department of Pathology, Verona University, Verona , Italy; h Department of Radiology, Uppsala University, Uppsala , Sweden; i Department of Pathology, Universitatsspital Zurich, Zurich , Switzerland; j Department of Endocrinology and Metabolism, Hadassah University, Jerusalem , Israel; k Department of Oncology, Alexander Fleming Institute, Buenos Aires , Argentina; l Laboratory of Molecular Imaging and Experimental Radiotherapy, Universite Catholique de Louvain, Brussels , Belgium; m Department of Pathology, University Hospital of Kiel, Kiel , Germany

Well-differentiated pancreatic tumor/carcinoma: Insulinoma

a Department of Internal Medicine, Section of Endocrinology, Erasmus MC, Rotterdam, The Netherlands; b Division of General Surgery, Department of Surgery, Medical University of Vienna, Vienna , Austria; c Hospices Civils de Lyon, Hopital Edouard-Herriot Service Central d‘Anatomie et Cytologie Pathologiques, Lyon , France; d Centre de Medecine Nucleaire, Universite Catholique de Louvain, Brussels , Belgium; e Department of Pathology, University of Kiel, Kiel , Germany; f B Unit of Surgery, Department of Surgery, University of Verona, Verona , Italy; g Department of Nuclear Medicine, Erasmus MC, Rotterdam , The Netherlands; h Department of Endocrine Oncology, University Hospital, Uppsala , Sweden; i Department of Internal Medicine, Division of Hepatology and Gastroenterology, Interdisciplinary Center of Metabolism and Endocrinology, Charite, Campus Virchow Hospital, University for Medicine Berlin, Berlin , Germany; j Service de Gastroenterologie-Pancreatologie, Pole des Maladies de l‘Appareil Digestif, Hopital Beaujon, Clichy , France; k Department of Pathology and Laboratory Medicine, Universita degli Studi, Parma, Italy; l Department of Endocrinology, Genoa University, Genoa , Italy

Positron Emission Tomography With Fluorodeoxyglucose for Suspected Head and Neck Tumor Recurrence in the Symptomatic Patient

Objective To analyze the impact of positron emission tomography with fluorodeoxyglucose (FDG‐PET) in the treatment of patients suspected of having head and neck cancer recurrence.

Inadequate detection of accessory spleens and splenosis with laparoscopic splenectomy. A shortcoming of the laparoscopic approach in hematologic diseases

AbstractBackground: The ultimate goal of surgery for hematological disorders is the complete removal of both the spleen and accessory spleens in order to avoid recurrence of the disease. Whereas splenectomy by open surgery provides excellent results, the validity of laparoscopic splenectomy in this regard remains unknown. Objective: The purpose of this study was to evaluate the detection of accessory spleens during laparoscopic splenectomy for hematologic diseases. Methods: We therefore evaluated the pre-, intra-, and postoperative detection of accessory spleens in a consecutive series of 18 patients treated by elective laparoscopic splenectomy for hematological diseases by using computed tomography (CT) and denatured red blood cell scintigraphy (DRBCS). Results: Preoperative CT, DRBCS, and laparoscopic exploration detected 25%, 25%, and 75% of accessory spleens, respectively. At time of laparoscopy, 16 accessory spleens were detected in seven of the 18 patients (41%). In two patients (11%), laparoscopic exploration failed to detect accessory spleens, whereas preoperative CT (one case) and DRBCS (one case) did reveal them. Postoperatively, during a mean follow-up of 28 months (median, 24; range, 12–44 months), nine patients (50%) showed persistence of splenic tissue by DRBCS, and three of them had signs of disease recurrence. Conclusions: This prospective clinical study suggests that elective laparoscopic surgery for hematological diseases does not allow complete detection of accessory spleens. Moreover, after such a laparoscopic approach, residual splenic tissue is detectable in half of the patients during the follow-up.

Well-differentiated gastric tumors/carcinomas

a Department of Gastroenterology, Beaujon Hospital, Clichy , France; b Department of Digestive and Liver Disease, Ospedale S. Andrea, Rome , Italy; c Department of Hepatology and Gastroenterology, CHU Bichat – B. Claude Bernard University, Paris , France; d Department of Pathology, Kantonsspital Baden , Switzerland; e Department of Gastroenterology, Massachussetts General Hospital, Boston , Mass. , USA; f B. Kos-Kudla, Department of Endocrinology, Slaska University, Zabrze , Poland; g Department of Surgery, UFR Bichat-Beaujon-Louis Mourier Hospital, Colombes , France; h Department of Oncology, Royal Free University, London , UK; i Department of Gastroenterology, Philipps University, Marburg , Germany; j Department of Surgery, Gothenburg University, Gothenburg , Sweden; k Department of Nuclear Medicine, Catholique de Louvain University, Brussels , Belgium; l Department of Nuclear Medicine, Erasmus MC University, Rotterdam , The Netherlands; m Department of Pathology and Laboratory Medicine, Universita degli Studi, Parma , Italy

Poorly differentiated carcinomas of the foregut (gastric, duodenal and pancreatic)

a Department of Pathology, Gothenburg University, Gothenburg , Sweden; b Department of Gastroenterology, Gasthuisberg University, Leuven , Belgium; c Department of Gastroenterology, Ospedale S. Andrea, Rome , Italy; d Department of Oncology, University of Texas, Houston, Tex. , USA; e Department of Endocrinology, Erlangen University, Erlangen , Germany; f Department of Oncology and Pathology, Royal Infirmary Hospital, Glasgow , UK; g Department of Oncology, Virgen de la Victoria Hospital, Malaga , Spain; h Department of Nuclear Medicine, Medizinische Hochschule Hannover, Hannover , Germany; i Department of Endocrinology, Erciyes University, Kayseri , Turkey; j Department of Surgery, Beaujon Hospital, Clichy , France; k Department of Nuclear Medicine, Catholique de Louvain University, Brussels , Belgium; l Department of Nuclear Medicine, Erasmus MC University, Rotterdam , The Netherlands; m Department of Gastroenterology, Royal Free Hospital, London , UK

Feasibility of 90Y TOF PET-based dosimetry in liver metastasis therapy using SIR-Spheres

Purpose90Y-labelled compounds used in targeted radiotherapy are usually imaged with SPECT by recording the bremsstrahlung X-rays of the β decay. The continuous shape of the X-ray spectrum induces the presence of a significant fraction of scatter rays in the acquisition energy window, reducing the accuracy of biodistribution and of dosimetry assessments.MethodsThe aim of this paper is to use instead the low branch of e− e+ pair production in the 90Y decay. After administration of 90Y-labelled SIR-Spheres by catheterization of both liver lobes, the activity distribution is obtained by 90Y time-of-flight (TOF) PET imaging. The activity distribution is convolved with a dose irradiation kernel in order to derive the regional dosimetry distribution.ResultsEvaluation on an anatomical phantom showed that the method provided an accurate dosimetry assessment. Preliminary results on a patient demonstrated a high-resolution absorbed dose distribution with a clear correlation with tumour response.ConclusionThis supports the implementation of 90Y PET in selective internal radiation therapy of the liver.

Somatostatin receptor: Scintigraphy and radionuclide therapy

Peptide receptor scintigraphy is more sensitive at the biological than anatomical level, in contrast to conventional imaging, which it complements. Neuroendocrine tumours have the most somatostatin receptors in vitro and their metastases are somatostatin receptor positive in vitro, so that [111In-DTPA-D-Phe1]octreotide (OCT) can be used to image them. OCT was compared with conventional imaging techniques (CON) in a European Multicentre Trial. In 350 evaluable patients, CON detected 88%, and OCT 80% (glucagonomas 100%, VIPomas 88%, carcinoids 87%, non-functioning islet cell tumours 82%, insulinomas 46%) of tumour sites but there was no systematic use of abdominal single-photon-emission computerised tomography. OCT demonstrated multiple tumour sites in 62 of 178 patients in whom CON had found only 1 lesion, with 60% confirmed. 12/16 lesions detected by OCT in 11 patients with no lesions according to CON were also confirmed. The impact of OCT on management was evaluated in 235 patients and affected 40%: it determined 29 surgical decisions, led to octreotide therapy in 47, and modified octreotide dose in 18. Six end-stage patients with neuroendocrine tumours were treated with OCT radionuclide therapy (up to a cumulative dose of 53 GBq per patient) in a phase I trial. There were no major side-effects after up to 2 years treatment, with impressive effects on hormone production and a likely anti-proliferative effect.

OctreoTherTM: Ongoing Early Clinical Development of a Somatostatin-Receptor-Targeted Radionuclide Antineoplastic Therapy

OctreoTherTM (90Y-DOTA-D-Phe1-Tyr3-octreotide, a.k.a. 90Y-SMT 487) consists of a somatostatin peptide analogue (Tyr3-octreotide), coupled with a complexing moiety (DOTA), and labeled with a tightly bound beta-emitter (yttrium-90). By targeting somatostatin receptor-positive tumors (as imaged by OctreaScan®) it may deliver a tumoricidal dose of radiation. Phase I clinical trials, conducted in patients with neuroendocrine tumors, established the safety and tolerability of the dose selected for further study and demonstrated the capacity of OctreoTher to deliver radiation doses to tumors that resulted in significant neuroendocrine tumor shrinkage. Novartis-sponsored phase II studies will soon begin to test the efficacy of OctreoTher in breast and small cell lung cancer. A fixed-dose regimen of 120 mCi/cycle × 3 cycles administered with concomitant amino acid infusion has been chosen for the study. Phase I data and published literature support that this fixed dose regimen will be safely tolerated.

Quantitation in PET using isotopes emitting prompt single gammas: application to yttrium-86

Several yttrium-90 labelled somatostatin analogues are now available for cancer radiotherapy. After injection, a large amount of the compound is excreted via the urinary tract, while a variable part is trapped in the tumour(s), allowing the curative effect. Unfortunately, the compound may also be trapped in critical tissues such as kidney or bone marrow. As a consequence, a method for assessment of individual biodistribution and pharmacokinetics is required to predict the maximum dose that can be safely injected into patients. However, 90Y, a pure β–particle emitter, cannot be used for quantitative imaging. Yttrium-86 is a positron emitter that allows imaging of tissue uptake using a PET camera. In addition to the positron, 86Y also emits a multitude of prompt single γ-rays, leading to significant overestimation of uptake when using classical reconstruction methods. We propose a patient-dependent correction method based on sinogram tail fitting using an 86Y point spread function library. When applied to abdominal phantom acquisition data, the proposed correction method significantly improved the accuracy of the quantification: the initial overestimation of background activity by 117% was reduced to 9%, while the initial error in respect of kidney uptake by 84% was reduced to 5%. In patient studies, the mean discrepancy between PET total body activity and the activity expected from urinary collections was reduced from 92% to 7%, showing the benefit of the proposed correction method.