Analysis of emission tomographic scan data: limitations imposed by resolution and background.
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A rat head holder for simultaneous scanning of two rats in small animal PET scanners: design, construction, feasibility testing and kinetic validationCurrent molecular imaging of spinal tumors in clinical practice.In vivo functional and anatomic imaging for assessment of in vivo gene transfer.Midbrain dopamine receptor availability is inversely associated with novelty-seeking traits in humansImage-guided PO2 probe measurements correlated with parametric images derived from 18F-fluoromisonidazole small-animal PET data in rats.Test-retest variability of high resolution positron emission tomography (PET) imaging of cortical serotonin (5HT2A) receptors in older, healthy adults.Quantification of mineralized bone response to prostate cancer by noninvasive in vivo microCT and non-destructive ex vivo microCT and DXA in a mouse model.Accuracy of 131I tumor quantification in radioimmunotherapy using SPECT imaging with an ultra-high-energy collimator: Monte Carlo studyMonte Carlo evaluation of object shape effects in iodine-131 SPET tumor activity quantificationQuantitative immunoPET of prostate cancer xenografts with 89Zr- and 124I-labeled anti-PSCA A11 minibodySimultaneous Tumor Segmentation, Image Restoration, and Blur Kernel Estimation in PET Using Multiple RegularizationsPET imaging for the quantification of biologically heterogeneous tumours: measuring the effect of relative position on image-based quantification of dose-painting targets.In vivo validation of reconstruction-based resolution recovery for human brain studies.Dopamine D2 receptor levels in striatum, thalamus, substantia nigra, limbic regions, and cortex in schizophrenic subjects.Technological development and advances in single-photon emission computed tomography/computed tomography.FBPA PET in boron neutron capture therapy for cancer: prediction of (10)B concentration in the tumor and normal tissue in a rat xenograft model.Design and implementation of an automated partial volume correction in PET: application to dopamine receptor quantification in the normal human striatumBrain aging research at the close of the 20th century: from bench to bedside.Performance evaluation of the Ingenuity TF PET/CT scanner with a focus on high count-rate conditions.Clinical significance of MRI/(18)F-FDG PET fusion imaging of the spinal cord in patients with cervical compressive myelopathy.Cortical and subcortical glucose metabolism in childhood epileptic encephalopathies.A method for model-free partial volume correction in oncological PET.Comparison of PET metabolic indices for the early assessment of tumour response in metastatic colorectal cancer patients treated by polychemotherapy.Scanning linear estimation: improvements over region of interest (ROI) methods.Design of a Multi-Pinhole Collimator for I-123 DaTscan Imaging on Dual-Headed SPECT Systems in Combination with a Fan-Beam CollimatorAn evaluation of iterative reconstruction strategies based on mediastinal lesion detection using hybrid Ga-67 SPECT imagesDiminishing the impact of the partial volume effect in cardiac SPECT perfusion imaging.[(18)F]Fallypride dopamine D2 receptor studies using delayed microPET scans and a modified Logan plot.Dopa decarboxylase activity of the living human brain.Kidney stone volume estimation from computerized tomography images using a model based method of correcting for the point spread function.Accuracy and precision of radioactivity quantification in nuclear medicine images.Resolution modeling in PET imaging: theory, practice, benefits, and pitfalls.A method for partial volume correction of PET-imaged tumor heterogeneity using expectation maximization with a spatially varying point spread function.Image-derived and arterial blood sampled input functions for quantitative PET imaging of the angiotensin II subtype 1 receptor in the kidney.SPECT/CT: an update on technological developments and clinical applications.Spreadsheet program for estimating recovery coefficient to get partial volume corrected standardized uptake value in clinical positron emission tomography-computed tomography studies.Simplified [18F]FDG image-derived input function using the left ventricle, liver, and one venous blood sampleExtrastriatal dopaminergic abnormalities of DA homeostasis in Parkinson's patients with medication-induced pathological gambling: a [11C] FLB-457 and PET study.A partial volume effect correction tailored for 18F-FDG-PET oncological studies.Image-derived input function in dynamic human PET/CT: methodology and validation with 11C-acetate and 18F-fluorothioheptadecanoic acid in muscle and 18F-fluorodeoxyglucose in brain.
P2860
Q28692386-0081A96E-7610-4858-85E8-196B52A9D32CQ30476277-D32C4610-47F9-46E9-AD0F-C96AD2AABC5AQ30489867-22C328F5-B1CD-42B0-80AE-1B22A74B49A1Q30490410-7223132F-2BF9-4DA3-8734-99C8411375B8Q30559873-41B2FF50-B885-4F8F-BB20-22D486BD10FAQ33478744-49F2044B-B094-4FF6-8860-5BB8EFB5F9E0Q33548724-02E09692-2B8E-4DDD-803E-E6B368C5A37FQ33613117-2D295767-5C6C-471C-B5CE-E1118EEB899BQ33699551-CC297D34-18A7-4A91-A3C0-884D71D27385Q33738280-88ADA2A7-3103-491A-AD0C-CF873D6CBB17Q33777233-A9F869D7-F0F4-4F0D-A3FE-7BCD7C1D3673Q34140212-6A47F65D-D44A-4FD4-9660-680E09E49EC7Q34170801-CC34C6C0-CA38-44A2-9481-5461A4129D09Q34183875-1EE2F410-58A9-4AE3-9F56-6987907FF9BFQ34626322-CAEDAC8F-F907-455B-BC0E-5D0687958A18Q34947079-699A54F4-5C8B-4AA8-8E61-E503C4CC2F8BQ35014986-E993E4EE-8253-4560-9B7E-08D735430097Q35236407-3F8BE4E3-B1A1-4CE1-B8D6-40406E7D1893Q35687966-93E1F989-ADAC-48F8-AB00-D4E20EE7EB7BQ36279435-9961B0D7-C8C1-4CD0-A9BF-D10520285B17Q36316993-52E85711-9654-45C3-9FAB-4F8723C902FEQ36411892-A2C9BBF9-2250-4D2F-BA67-A561DD5E1C7CQ36508524-FECB2422-CBD1-4B5B-8954-F89E46040D1EQ36731371-8AB42304-3106-460F-9986-0CAD6D7866C5Q36894330-AAC0368A-EE08-4110-9A6D-75A9E6865504Q37154372-422F1DD6-6968-44B9-9C50-311EA3F78F36Q37334709-0E5C6B9C-C6B7-43EC-B0F0-DED3F8B49736Q37407159-8F5ABCEE-0D75-44F0-B1D7-EB1F591CD414Q37459264-D4A0B04C-AC47-46D6-A583-3219F55D00ABQ37590121-DC75759F-5685-4546-BDA0-473EB771DF0FQ37999911-07C125E1-E78E-48CE-A7DC-2EBC9BFCC73CQ38110325-F4F2E89E-2105-48D9-88DB-1FF6D8A57B7EQ38447419-65605923-C0D3-4354-A542-6B64E0F69E99Q38947793-42AC1E67-9025-4BB5-B446-EA49EF8D31BBQ39009093-09CBC40F-61A5-4D13-A715-807351F34163Q41090789-CE5C1082-14C6-4737-BE1B-953EE81A9737Q42017971-BEA1C559-8312-46E3-86CF-0AF534A232CCQ42077769-6F61FDD2-8DAE-4DAE-8799-BCBEE7BA15F8Q42255415-A963C08D-3645-4849-BFF4-F77B641A8E89Q42589662-02A03F21-1A57-40DD-9811-1B1A11966FE2
P2860
Analysis of emission tomographic scan data: limitations imposed by resolution and background.
description
1984 nî lūn-bûn
@nan
1984 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
1984 թվականի հունիսին հրատարակված գիտական հոդված
@hy
1984年の論文
@ja
1984年論文
@yue
1984年論文
@zh-hant
1984年論文
@zh-hk
1984年論文
@zh-mo
1984年論文
@zh-tw
1984年论文
@wuu
name
Analysis of emission tomograph ...... by resolution and background.
@ast
Analysis of emission tomograph ...... by resolution and background.
@en
Analysis of emission tomograph ...... by resolution and background.
@nl
type
label
Analysis of emission tomograph ...... by resolution and background.
@ast
Analysis of emission tomograph ...... by resolution and background.
@en
Analysis of emission tomograph ...... by resolution and background.
@nl
prefLabel
Analysis of emission tomograph ...... by resolution and background.
@ast
Analysis of emission tomograph ...... by resolution and background.
@en
Analysis of emission tomograph ...... by resolution and background.
@nl
P2093
P1476
Analysis of emission tomograph ...... by resolution and background.
@en
P2093
P304
P577
1984-06-01T00:00:00Z