Your search keyword '"Gillett, Daniel [0000-0002-9773-6502]"' showing total 5 results

1. Localization of TSH-secreting pituitary adenoma using 11C-methionine image subtraction

Author

Daniel Gillett, Russell Senanayake, James MacFarlane, Merel van der Meulen, Olympia Koulouri, Andrew S. Powlson, Rosy Crawford, Bethany Gillett, Nick Bird, Sarah Heard, Angelos Kolias, Richard Mannion, Luigi Aloj, Iosif A. Mendichovszky, Heok Cheow, Waiel A. Bashari, Mark Gurnell, Gillett, Daniel [0000-0002-9773-6502], Kolias, Angelos [0000-0003-3992-0587], Aloj, Luigi [0000-0002-7452-4961], Gurnell, Mark [0000-0001-5745-6832], and Apollo - University of Cambridge Repository

Subjects

Normalization, 11C-methionine PET, Subtraction imaging, Radiology, Nuclear Medicine and imaging, Human pituitary tumors, Original Research

Abstract

Background Pituitary adenomas (PA) affect ~ 1:1200 of the population and can cause a wide range of symptoms due to hormone over-secretion, loss of normal pituitary gland function and/or compression of visual pathways, resulting in significantly impaired quality of life. Surgery is potentially curative if the location of the adenoma can be determined. However, standard structural (anatomical) imaging, in the form of MRI, is unable to locate all tumors, especially microadenomas (11C-methionine PET/CT (Met-PET)] can facilitate tumor detection, although may be inconclusive when the adenoma is less metabolically active. We, therefore, explored whether subtraction imaging, comparing findings between two Met-PET scans with medical therapy-induced suppression of tumor activity in the intervening period, could increase confidence in adenoma localization. In addition, we assessed whether normalization to a reference region improved consistency of pituitary gland signal in healthy volunteers who underwent two Met-PET scans without medical suppression. Results We found that the mean percentage differences in maximum pituitary uptake between two Met-PET scans in healthy volunteers were 2.4% for (SUVr) [cerebellum], 8.8% for SUVr [pons], 5.2% for SUVr [gray matter] and 23.1% for the SUVbw [no region]. Laterality, as measured by contrast–noise ratio (CNR), indicated the correct location of the adenoma in all three image types with mean CNR values of 6.2, 8.1 and 11.1 for SUVbw, SUVbwSub and SUVrSub [cerebellum], respectively. Subtraction imaging improved CNR in 60% and 100% of patients when using images generated from SUVbw [no region] and SUVr [cerebellum] scans compared to standard clinical SUVbw imaging. Conclusions Met-PET scans should be normalized to the cerebellum to minimize the effects of physiological variation in pituitary gland uptake of 11C-methionine, especially when comparing serial imaging. Subtraction imaging following endocrine suppression of tumor function improved lateralization of PA when compared with single time point clinical Met-PET but, importantly, only if the images were normalized to the cerebellum prior to subtraction.

Published

2022

2. Obesity due to melanocortin 4 receptor (MC4R) deficiency is associated with delayed gastric emptying

Author

I. Sadaf Farooqi, Eleonora Seelig, Evelyn Shin, John R. Buscombe, Agatha A. van der Klaauw, Julia M. Keogh, Daniel Gillett, Elana Henning, Gillett, Daniel [0000-0002-9773-6502], van der Klaauw, Agatha A [0000-0001-6971-8828], Farooqi, I Sadaf [0000-0001-7609-3504], and Apollo - University of Cambridge Repository

Subjects

medicine.medical_specialty, obesity, Gastroparesis, Endocrinology, Diabetes and Metabolism, Enteroendocrine cell, MC4R, Endocrinology, gastric emptying, Internal medicine, medicine, Humans, Peptide YY, Meal, Gastric emptying, PYY, business.industry, digestive, oral, and skin physiology, Area under the curve, medicine.disease, Postprandial Period, Obesity, Melanocortin 4 receptor, Postprandial, Receptor, Melanocortin, Type 4, business, hormones, hormone substitutes, and hormone antagonists, Hormone

Abstract

Objective People who are severely obese due to melanocortin-4 receptor (MC4R) deficiency experience hyperphagia and impaired fullness after a meal (satiety). Meal-induced satiety is influenced by hormones, such as peptide-YY (PYY), which are released by enteroendocrine cells upon nutrient delivery to the small intestine. Design We investigated whether gastric emptying and PYY levels are altered in MC4R deficiency. Methods Gastric emptying was measured with a gastric scintigraphy protocol using technetium-99m (99 Tcm )-Tin Colloid for 3.5 h in individuals with loss of function MC4R variants and a control group of similar age and weight. In a separate study, we measured plasma PYY levels before and at multiple time points after three standardised meals given to individuals with MC4R deficiency and controls. Fasting PYY (basal secretion) and postprandial PYY levels were measured and the area under the curve and inter-meal peak were calculated. Results We found that gastric emptying time was significantly delayed and percentage meal retention increased in individuals with MC4R deficiency compared to obese controls. In addition, fasting and mean PYY secretion throughout the day were decreased in MC4R deficiency, whereas postprandial PYY secretion was unaltered. Conclusion Delayed gastric emptying and reduced basal PYY secretion may contribute to impaired satiety in people with obesity due to MC4R deficiency.

Published

2021

3. Methods of 3D printing models of pituitary tumors

Author

Andrew S Powlson, Richard Mannion, Waiel A Bashari, Mark Gurnell, Daniel Marsden, H.K. Cheow, Merel van der Meulen, Angelos G. Kolias, Olympia Koulouri, James MacFarlane, Iosif Mendichovszky, Daniel Gillett, Nick Bird, Russell Senanayake, Gillett, Daniel [0000-0002-9773-6502], and Apollo - University of Cambridge Repository

Subjects

medicine.medical_specialty, Adenoma, PET/CT, education, R895-920, Biomedical Engineering, 3D printing, Surgical planning, Planned procedure, Medical physics. Medical radiology. Nuclear medicine, Pituitary adenoma, Cost analysis, Medicine, Radiology, Nuclear Medicine and imaging, Desktop Vat Polymerization (Stereolithography), PET-CT, medicine.diagnostic_test, business.industry, Research, Pituitary tumors, Magnetic resonance imaging, medicine.disease, Clinical utility, Computer Science Applications, Pituitary, Radiology, business, MRI

Abstract

Funder: National Institute for Health Research; doi: http://dx.doi.org/10.13039/501100000272, Background: Pituitary adenomas can give rise to a variety of clinical disorders and surgery is often the primary treatment option. However, preoperative magnetic resonance imaging (MRI) does not always reliably identify the site of an adenoma. In this setting molecular (functional) imaging (e.g. 11C-methionine PET/CT) may help with tumor localisation, although interpretation of these 2D images can be challenging. 3D printing of anatomicalal models for other indications has been shown to aid surgical planning and improve patient understanding of the planned procedure. Here, we explore the potential utility of four types of 3D printing using PET/CT and co-registered MRI for visualising pituitary adenomas. Methods: A 3D patient-specific model based on a challenging clinical case was created by segmenting the pituitary gland, pituitary adenoma, carotid arteries and bone using contemporary PET/CT and MR images. The 3D anatomical models were printed using VP, MEX, MJ and PBF 3D printing methods. Different anatomicalal structures were printed in color with the exception of the PBF anatomical model where a single color was used. The anatomical models were compared against the computer model to assess printing accuracy. Three groups of clinicians (endocrinologists, neurosurgeons and ENT surgeons) assessed the anatomical models for their potential clinical utility. Results: All of the printing techniques produced anatomical models which were spatially accurate, with the commercial printing techniques (MJ and PBF) and the consumer printing techniques (VP and MEX) demonstrating comparable findings (all techniques had mean spatial differences from the computer model of < 0.6 mm). The MJ, VP and MEX printing techniques yielded multicolored anatomical models, which the clinicians unanimously agreed would be preferable to use when talking to a patient; in contrast, 50%, 40% and 0% of endocrinologists, neurosurgeons and ENT surgeons respectively would consider using the PBF model. Conclusion: 3D anatomical models of pituitary tumors were successfully created from PET/CT and MRI using four different 3D printing techniques. However, the expert reviewers unanimously preferred the multicolor prints. Importantly, the consumer printers performed comparably to the commercial MJ printing technique, opening the possibility that these methods can be adopted into routine clinical practice with only a modest investment.

Published

2021

4. 3D printing 18F radioactive phantoms for PET imaging

Author

Safia Ballout, Nick Bird, Iosif Mendichovszky, Daniel Gillett, Luigi Aloj, Bala Attili, Daniel Marsden, Mark Gurnell, Sarah Heard, Gillett, Daniel [0000-0002-9773-6502], and Apollo - University of Cambridge Repository

Subjects

Scanner, Radiation, Single use, Materials science, business.industry, R895-920, Biomedical Engineering, Quality control, 3D printing, Pet imaging, equipment and supplies, Phantoms, Medical physics. Medical radiology. Nuclear medicine, PET, 18F, Pet scanner, Human anatomy, Radiology, Nuclear Medicine and imaging, business, Instrumentation, Gamma counter, Biomedical engineering

Abstract

Purpose Phantoms are routinely used in molecular imaging to assess scanner performance. However, traditional phantoms with fillable shapes do not replicate human anatomy. 3D-printed phantoms have overcome this by creating phantoms which replicate human anatomy which can be filled with radioactive material. The problem with these is that small objects suffer to a greater extent than larger objects from the effects of inactive walls, and therefore, phantoms without these are desirable. The purpose of this study was to explore the feasibility of creating resin-based 3D-printed phantoms using 18F. Methods Radioactive resin was created using an emulsion of printer resin and 18F-FDG. A series of test objects were printed including twenty identical cylinders, ten spheres with increasing diameters (2 to 20 mm), and a double helix. Radioactive concentration uniformity, printing accuracy and the amount of leaching were assessed. Results Creating radioactive resin was simple and effective. The radioactive concentration was uniform among identical objects; the CoV of the signal was 0.7% using a gamma counter. The printed cylinders and spheres were found to be within 4% of the model dimensions. A double helix was successfully printed as a test for the printer and appeared as expected on the PET scanner. The amount of radioactivity leached into the water was measurable (0.72%) but not visible above background on the imaging. Conclusions Creating an 18F radioactive resin emulsion is a simple and effective way to create accurate and complex phantoms without inactive walls. This technique could be used to print clinically realistic phantoms. However, they are single use and cannot be made hollow without an exit hole. Also, there is a small amount of leaching of the radioactivity to take into consideration.

Published

2021

5. 3D printing 18 F radioactive phantoms for PET imaging

Author

Gillett, Daniel, Marsden, Daniel, Ballout, Safia, Attili, Bala, Bird, Nick, Heard, Sarah, Gurnell, Mark, Mendichovszky, Iosif A., Aloj, Luigi, Gillett, Daniel [0000-0002-9773-6502], and Apollo - University of Cambridge Repository

Subjects

PET, 18F, Quality control, 3D printing, equipment and supplies, Phantoms, Original Research

Abstract

Purpose: Phantoms are routinely used in molecular imaging to assess scanner performance. However, traditional phantoms with fillable shapes do not replicate human anatomy. 3D-printed phantoms have overcome this by creating phantoms which replicate human anatomy which can be filled with radioactive material. The problem with these is that small objects suffer to a greater extent than larger objects from the effects of inactive walls, and therefore, phantoms without these are desirable. The purpose of this study was to explore the feasibility of creating resin-based 3D-printed phantoms using 18F. Methods: Radioactive resin was created using an emulsion of printer resin and 18F-FDG. A series of test objects were printed including twenty identical cylinders, ten spheres with increasing diameters (2 to 20 mm), and a double helix. Radioactive concentration uniformity, printing accuracy and the amount of leaching were assessed. Results: Creating radioactive resin was simple and effective. The radioactive concentration was uniform among identical objects; the CoV of the signal was 0.7% using a gamma counter. The printed cylinders and spheres were found to be within 4% of the model dimensions. A double helix was successfully printed as a test for the printer and appeared as expected on the PET scanner. The amount of radioactivity leached into the water was measurable (0.72%) but not visible above background on the imaging. Conclusions: Creating an 18F radioactive resin emulsion is a simple and effective way to create accurate and complex phantoms without inactive walls. This technique could be used to print clinically realistic phantoms. However, they are single use and cannot be made hollow without an exit hole. Also, there is a small amount of leaching of the radioactivity to take into consideration.

Published

2021