Your search keyword '"Iqbal, Zohaib"' showing total 9 results

1. Modeling Elekta VersaHD using the Varian Eclipse treatment planning system for photon beams: A single-institution experience.

Author

Zhang Y, Le AH, Tian Z, Iqbal Z, Chiu T, Gu X, Pugachev A, Reynolds R, Park YK, Lin MH, and Stojadinovic S

Subjects

Humans, Organs at Risk radiation effects, Radiotherapy Dosage, Radiotherapy, Intensity-Modulated methods, Algorithms, Neoplasms radiotherapy, Particle Accelerators instrumentation, Phantoms, Imaging, Photons, Radiotherapy Planning, Computer-Assisted methods

Abstract

The aim of this study was to report a single-institution experience and commissioning data for Elekta VersaHD linear accelerators (LINACs) for photon beams in the Eclipse treatment planning system (TPS). Two VersaHD LINACs equipped with 160-leaf collimators were commissioned. For each energy, the percent-depth-dose (PDD) curves, beam profiles, output factors, leaf transmission factors and dosimetric leaf gaps (DLGs) were acquired in accordance with the AAPM task group reports No. 45 and No. 106 and the vendor-supplied documents. The measured data were imported into Eclipse TPS to build a VersaHD beam model. The model was validated by creating treatment plans spanning over the full-spectrum of treatment sites and techniques used in our clinic. The quality assurance measurements were performed using MatriXX, ionization chamber, and radiochromic film. The DLG values were iteratively adjusted to optimize the agreement between planned and measured doses. Mobius, an independent LINAC logfile-based quality assurance tool, was also commissioned both for routine intensity-modulated radiation therapy (IMRT) QA and as a secondary check for the Eclipse VersaHD model. The Eclipse-generated VersaHD model was in excellent agreement with the measured PDD curves and beam profiles. The measured leaf transmission factors were less than 0.5% for all energies. The model validation study yielded absolute point dose agreement between ionization chamber measurements and Eclipse within ±4% for all cases. The comparison between Mobius and Eclipse, and between Mobius and ionization chamber measurements lead to absolute point dose agreement within ±5%. The corresponding 3D dose distributions evaluated with 3%global/2mm gamma criteria resulted in larger than 90% passing rates for all plans. The Eclipse TPS can model VersaHD LINACs with clinically acceptable accuracy. The model validation study and comparisons with Mobius demonstrated that the modeling of VersaHD in Eclipse necessitates further improvement to provide dosimetric accuracy on par with Varian LINACs., (© 2019 The Authors. Journal of Applied Clinical Medical Physics published by Wiley Periodicals, Inc. on behalf of American Association of Physicists in Medicine.)

Published

2019

2. Covariance J-resolved spectroscopy: Theory and application in vivo.

Author

Iqbal Z, Verma G, Kumar A, and Thomas MA

Subjects

Computer Simulation, Humans, Magnetic Resonance Imaging, Middle Aged, Algorithms, Magnetic Resonance Spectroscopy

Abstract

Magnetic resonance spectroscopy (MRS) is a powerful tool capable of investigating the metabolic status of several tissues in vivo. In particular, single-voxel-based 1 H spectroscopy provides invaluable biochemical information from a volume of interest (VOI) and has therefore been used in a variety of studies. Unfortunately, typical one-dimensional MRS data suffer from severe signal overlap and thus important metabolites are difficult to distinguish. One method that is used to disentangle overlapping resonances is the two-dimensional J-resolved spectroscopy (JPRESS) experiment. Due to the long acquisition duration of the JPRESS experiment, a limited number of points are acquired in the indirect dimension, leading to poor spectral resolution along this dimension. Poor spectral resolution is problematic because proper peak assignment may be hindered, which is why the zero-filling method is often used to improve resolution as a post-processing step. However, zero-filling leads to spectral artifacts, which may affect visualization and quantitation of spectra. A novel method utilizing a covariance transformation, called covariance J-resolved spectroscopy (CovJ), was developed in order to improve spectral resolution along the indirect dimension (F 1 ). Comparison of simulated data demonstrates that peak structures remain qualitatively similar between JPRESS and the novel method along the diagonal region (F 1 = 0 Hz), whereas differences arise in the cross-peak (F 1 ≠0 Hz) regions. In addition, quantitative results of in vivo JPRESS data acquired on a 3T scanner show significant correlations (r 2 >0.86, p<0.001) when comparing the metabolite concentrations between the two methods. Finally, a quantitation algorithm, 'COVariance Spectral Evaluation of 1 H Acquisitions using Representative prior knowledge' (Cov-SEHAR), was developed in order to quantify γ-aminobutyric acid and glutamate from the CovJ spectra. These preliminary findings indicate that the CovJ method may be used to improve spectral resolution without hindering metabolite quantitation for J-resolved spectra., (Copyright © 2017 John Wiley & Sons, Ltd.)

Published

2017

3. Prior-knowledge Fitting of Accelerated Five-dimensional Echo Planar J-resolved Spectroscopic Imaging: Effect of Nonlinear Reconstruction on Quantitation.

Author

Iqbal Z, Wilson NE, and Thomas MA

Subjects

Adult, Brain metabolism, Healthy Volunteers, Humans, Metabolome, Prospective Studies, Quality Control, Algorithms, Brain diagnostic imaging, Echo-Planar Imaging methods, Image Processing, Computer-Assisted methods, Phantoms, Imaging

Abstract

1 H Magnetic Resonance Spectroscopic imaging (SI) is a powerful tool capable of investigating metabolism in vivo from mul- tiple regions. However, SI techniques are time consuming, and are therefore difficult to implement clinically. By applying non-uniform sampling (NUS) and compressed sensing (CS) reconstruction, it is possible to accelerate these scans while re- taining key spectral information. One recently developed method that utilizes this type of acceleration is the five-dimensional echo planar J-resolved spectroscopic imaging (5D EP-JRESI) sequence, which is capable of obtaining two-dimensional (2D) spectra from three spatial dimensions. The prior-knowledge fitting (ProFit) algorithm is typically used to quantify 2D spectra in vivo, however the effects of NUS and CS reconstruction on the quantitation results are unknown. This study utilized a simulated brain phantom to investigate the errors introduced through the acceleration methods. Errors (normalized root mean square error >15%) were found between metabolite concentrations after twelve-fold acceleration for several low concentra- tion (<2 mM) metabolites. The Cramér Rao lower bound% (CRLB%) values, which are typically used for quality control, were not reflective of the increased quantitation error arising from acceleration. Finally, occipital white (OWM) and gray (OGM) human brain matter were quantified in vivo using the 5D EP-JRESI sequence with eight-fold acceleration.

Published

2017

4. Accelerated five-dimensional echo planar J-resolved spectroscopic imaging: Implementation and pilot validation in human brain.

Author

Wilson NE, Iqbal Z, Burns BL, Keller M, and Thomas MA

Subjects

Adult, Brain anatomy & histology, Female, Humans, Image Enhancement methods, Male, Pilot Projects, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Brain metabolism, Echo-Planar Imaging methods, Image Interpretation, Computer-Assisted methods, Imaging, Three-Dimensional methods, Molecular Imaging methods

Abstract

Purpose: To implement an accelerated five-dimensional (5D) echo-planar J-resolved spectroscopic imaging sequence combining 3 spatial and 2 spectral encoding dimensions and to apply the sequence in human brain., Methods: An echo planar readout was used to acquire a single spatial and a single spectral dimension during one readout. Nonuniform sampling was applied to the two phase-encoded spatial directions and the indirect spectral dimension. Nonlinear reconstruction was used to minimize the ℓ1-norm or the total variation and included a spectral mask to enhance sparsity. Retrospective reconstructions at multiple undersamplings were performed in phantom. Ten healthy volunteers were scanned with 8× undersampling and compared to a fully sampled single slice scan., Results: Retrospective reconstruction of fully sampled phantom data showed excellent quality at 4×, 8×, 12×, and 16× undersampling using either reconstruction method. Reconstruction of prospectively acquired in vivo scans with 8× undersampling showed excellent quality in the occipito-parietal lobes and good quality in the frontal lobe, consistent with the fully sampled single slice scan., Conclusion: By utilizing nonuniform sampling with nonlinear reconstruction, 2D J-resolved spectra can be acquired over a 3D spatial volume with a total scan time of 20 min, which is reasonable for in vivo studies., (© 2015 Wiley Periodicals, Inc.)

Published

2016

5. Non-uniformly weighted sampling for faster localized two-dimensional correlated spectroscopy of the brain in vivo

Author

Verma, Gaurav, Chawla, Sanjeev, Nagarajan, Rajakumar, Iqbal, Zohaib, Thomas, M Albert, and Poptani, Harish

Subjects

Medical and Biological Physics, Physical Sciences, Biomedical Imaging, Bioengineering, Clinical Research, Adult, Algorithms, Brain, Brain Chemistry, Computer Simulation, Healthy Volunteers, Humans, Magnetic Resonance Imaging, Magnetic Resonance Spectroscopy, Phantoms, Imaging, Signal-To-Noise Ratio, Localized correlated spectroscopy, Magnetic resonance spectroscopy, Uniformly averaged, Non-uniformly weighted sampling, NAA, Cr, Ch, GSH, GABA, Coil Combination, Two-dimensional L-COSY, NAA, Cr, Ch, GSH, GABA, Engineering, Biophysics, Physical sciences

Abstract

Two-dimensional localized correlated spectroscopy (2D L-COSY) offers greater spectral dispersion than conventional one-dimensional (1D) MRS techniques, yet long acquisition times and limited post-processing support have slowed its clinical adoption. Improving acquisition efficiency and developing versatile post-processing techniques can bolster the clinical viability of 2D MRS. The purpose of this study was to implement a non-uniformly weighted sampling (NUWS) scheme for faster acquisition of 2D-MRS. A NUWS 2D L-COSY sequence was developed for 7T whole-body MRI. A phantom containing metabolites commonly observed in the brain at physiological concentrations was scanned ten times with both the NUWS scheme of 12:48 duration and a 17:04 constant eight-average sequence using a 32-channel head coil. 2D L-COSY spectra were also acquired from the occipital lobe of four healthy volunteers using both the proposed NUWS and the conventional uniformly-averaged L-COSY sequence. The NUWS 2D L-COSY sequence facilitated 25% shorter acquisition time while maintaining comparable SNR in humans (+0.3%) and phantom studies (+6.0%) compared to uniform averaging. NUWS schemes successfully demonstrated improved efficiency of L-COSY, by facilitating a reduction in scan time without affecting signal quality.

Published

2017

6. Pilot Assessment of Brain Metabolism in Perinatally HIV-Infected Youths Using Accelerated 5D Echo Planar J-Resolved Spectroscopic Imaging.

Author

Iqbal, Zohaib, Wilson, Neil E, Keller, Margaret A, Michalik, David E, Church, Joseph A, Nielsen-Saines, Karin, Deville, Jaime, Souza, Raissa, Brecht, Mary-Lynn, and Thomas, M Albert

Subjects

Brain, Humans, HIV Infections, AIDS Dementia Complex, Choline, Creatine, Aspartic Acid, Glutamic Acid, Anti-HIV Agents, Echo-Planar Imaging, Case-Control Studies, Pilot Projects, Energy Metabolism, Algorithms, Adolescent, Infant, Newborn, Female, Male, Infectious Disease Transmission, Vertical, Young Adult, Functional Neuroimaging, Infant, Newborn, Infectious Disease Transmission, Vertical, General Science & Technology

Abstract

PurposeTo measure cerebral metabolite levels in perinatally HIV-infected youths and healthy controls using the accelerated five dimensional (5D) echo planar J-resolved spectroscopic imaging (EP-JRESI) sequence, which is capable of obtaining two dimensional (2D) J-resolved spectra from three spatial dimensions (3D).Materials and methodsAfter acquisition and reconstruction of the 5D EP-JRESI data, T1-weighted MRIs were used to classify brain regions of interest for HIV patients and healthy controls: right frontal white (FW), medial frontal gray (FG), right basal ganglia (BG), right occipital white (OW), and medial occipital gray (OG). From these locations, respective J-resolved and TE-averaged spectra were extracted and fit using two different quantitation methods. The J-resolved spectra were fit using prior knowledge fitting (ProFit) while the TE-averaged spectra were fit using the advanced method for accurate robust and efficient spectral fitting (AMARES).ResultsQuantitation of the 5D EP-JRESI data using the ProFit algorithm yielded significant metabolic differences in two spatial locations of the perinatally HIV-infected youths compared to controls: elevated NAA/(Cr+Ch) in the FW and elevated Asp/(Cr+Ch) in the BG. Using the TE-averaged data quantified by AMARES, an increase of Glu/(Cr+Ch) was shown in the FW region. A strong negative correlation (r < -0.6) was shown between tCh/(Cr+Ch) quantified using ProFit in the FW and CD4 counts. Also, strong positive correlations (r > 0.6) were shown between Asp/(Cr+Ch) and CD4 counts in the FG and BG.ConclusionThe complimentary results using ProFit fitting of J-resolved spectra and AMARES fitting of TE-averaged spectra, which are a subset of the 5D EP-JRESI acquisition, demonstrate an abnormal energy metabolism in the brains of perinatally HIV-infected youths. This may be a result of the HIV pathology and long-term combinational anti-retroviral therapy (cART). Further studies of larger perinatally HIV-infected cohorts are necessary to confirm these findings.

Published

2016

7. Correlated spectroscopic imaging of calf muscle in three spatial dimensions using group sparse reconstruction of undersampled single and multichannel data

Author

Wilson, Neil E, Burns, Brian L, Iqbal, Zohaib, and Thomas, M Albert

Subjects

Biomedical Imaging, Bioengineering, Clinical Research, Adult, Algorithms, Humans, Imaging, Three-Dimensional, Magnetic Resonance Imaging, Middle Aged, Muscle, Skeletal, Signal Processing, Computer-Assisted, EP-COSI, compressed sensing, nonuniform sampling, group sparsity, calf muscle, 3D spectroscopic imaging, Biomedical Engineering, Nuclear Medicine & Medical Imaging

Abstract

PurposeTo implement a 5D (three spatial + two spectral) correlated spectroscopic imaging sequence for application to human calf.Theory and methodsNonuniform sampling was applied across the two phase encoded dimensions and the indirect spectral dimension of an echo planar-correlated spectroscopic imaging sequence. Reconstruction was applied that minimized the group sparse mixed ℓ2,1-norm of the data. Multichannel data were compressed using a sensitivity map-based approach with a spatially dependent transform matrix and utilized the self-sparsity of the individual coil images to simplify the reconstruction.ResultsSingle channel data with 8× and 16× undersampling are shown in the calf of a diabetic patient. A 15-channel scan with 12× undersampling of a healthy volunteer was reconstructed using 5 virtual channels and compared to a fully sampled single slice scan. Group sparse reconstruction faithfully reconstructs the lipid cross peaks much better than ℓ1 minimization.ConclusionCOSY spectra can be acquired over a 3D spatial volume with scan time under 15 min using echo planar readout with highly undersampled data and group sparse reconstruction.

Published

2015

8. Covariance J-resolved spectroscopy: Theory and application in vivo

Author

Iqbal, Zohaib, Verma, Gaurav, Kumar, Anand, and Thomas, M Albert

Subjects

Magnetic Resonance Spectroscopy, J-resolved spectroscopy (JPRESS), Clinical Sciences, Biomedical Engineering, Bioengineering, Middle Aged, Magnetic Resonance Spectroscopy (MRS), Magnetic Resonance Imaging, J-resolved spectroscopy, prior-knowledge fitting, Nuclear Medicine & Medical Imaging, Medicinal and Biomolecular Chemistry, enhanced spectral resolution, Biomedical Imaging, Humans, Computer Simulation, covariance NMR, human brain, Algorithms

Abstract

Magnetic resonance spectroscopy (MRS) is a powerful tool capable of investigating the metabolic status of several tissues in vivo. In particular, single-voxel-based 1 H spectroscopy provides invaluable biochemical information from a volume of interest (VOI) and has therefore been used in a variety of studies. Unfortunately, typical one-dimensional MRS data suffer from severe signal overlap and thus important metabolites are difficult to distinguish. One method that is used to disentangle overlapping resonances is the two-dimensional J-resolved spectroscopy (JPRESS) experiment. Due to the long acquisition duration of the JPRESS experiment, a limited number of points are acquired in the indirect dimension, leading to poor spectral resolution along this dimension. Poor spectral resolution is problematic because proper peak assignment may be hindered, which is why the zero-filling method is often used to improve resolution as a post-processing step. However, zero-filling leads to spectral artifacts, which may affect visualization and quantitation of spectra. A novel method utilizing a covariance transformation, called covariance J-resolved spectroscopy (CovJ), was developed in order to improve spectral resolution along the indirect dimension (F1 ). Comparison of simulated data demonstrates that peak structures remain qualitatively similar between JPRESS and the novel method along the diagonal region (F1 = 0 Hz), whereas differences arise in the cross-peak (F1 ≠0 Hz) regions. In addition, quantitative results of in vivo JPRESS data acquired on a 3T scanner show significant correlations (r2 >0.86, p

Published

2017

9. Accelerated Five-Dimensional Echo Planar J-Resolved Spectroscopic Imaging: Implementation and Pilot Validation in Human Brain

Author

Wilson, Neil E, Iqbal, Zohaib, Burns, Brian L, Keller, Margaret, and Thomas, M Albert

Subjects

Adult, Male, Echo-Planar Imaging, Biomedical Engineering, Brain, Reproducibility of Results, Pilot Projects, Image Enhancement, Sensitivity and Specificity, Imaging, Molecular Imaging, 3D spectroscopic imaging, Nuclear Medicine & Medical Imaging, Computer-Assisted, nonuniform sampling, Three-Dimensional, Humans, Female, echo-planar J-resolved spectroscopic imaging, J-resolved spectroscopic imaging, Image Interpretation, human brain, Algorithms, compressed sensing

Abstract

To implement an accelerated five-dimensional (5D) echo-planar J-resolved spectroscopic imaging sequence combining 3 spatial and 2 spectral encoding dimensions and to apply the sequence in human brain.An echo planar readout was used to acquire a single spatial and a single spectral dimension during one readout. Nonuniform sampling was applied to the two phase-encoded spatial directions and the indirect spectral dimension. Nonlinear reconstruction was used to minimize the ℓ1-norm or the total variation and included a spectral mask to enhance sparsity. Retrospective reconstructions at multiple undersamplings were performed in phantom. Ten healthy volunteers were scanned with 8× undersampling and compared to a fully sampled single slice scan.Retrospective reconstruction of fully sampled phantom data showed excellent quality at 4×, 8×, 12×, and 16× undersampling using either reconstruction method. Reconstruction of prospectively acquired in vivo scans with 8× undersampling showed excellent quality in the occipito-parietal lobes and good quality in the frontal lobe, consistent with the fully sampled single slice scan.By utilizing nonuniform sampling with nonlinear reconstruction, 2D J-resolved spectra can be acquired over a 3D spatial volume with a total scan time of 20 min, which is reasonable for in vivo studies. Magn Reson Med 75:42-51, 2016. © 2015 Wiley Periodicals, Inc.

Published

2016