Your search keyword '"Iqbal, Zohaib"' showing total 42 results

1. Deep learning can accelerate and quantify simulated localized correlated spectroscopy

Author

Iqbal, Zohaib, Iqbal, Zohaib, Dan, Nguyen, Thomas, Michael Albert, Jiang, Steve, Iqbal, Zohaib, Iqbal, Zohaib, Dan, Nguyen, Thomas, Michael Albert, and Jiang, Steve

Abstract

Nuclear magnetic resonance spectroscopy (MRS) allows for the determination of atomic structures and concentrations of different chemicals in a biochemical sample of interest. MRS is used in vivo clinically to aid in the diagnosis of several pathologies that affect metabolic pathways in the body. Typically, this experiment produces a one dimensional (1D) 1H spectrum containing several peaks that are well associated with biochemicals, or metabolites. However, since many of these peaks overlap, distinguishing chemicals with similar atomic structures becomes much more challenging. One technique capable of overcoming this issue is the localized correlated spectroscopy (L-COSY) experiment, which acquires a second spectral dimension and spreads overlapping signal across this second dimension. Unfortunately, the acquisition of a two dimensional (2D) spectroscopy experiment is extremely time consuming. Furthermore, quantitation of a 2D spectrum is more complex. Recently, artificial intelligence has emerged in the field of medicine as a powerful force capable of diagnosing disease, aiding in treatment, and even predicting treatment outcome. In this study, we utilize deep learning to: 1) accelerate the L-COSY experiment and 2) quantify L-COSY spectra. We demonstrate that our deep learning model greatly outperforms compressed sensing based reconstruction of L-COSY spectra at higher acceleration factors. Specifically, at four-fold acceleration, our method has less than 5% normalized mean squared error, whereas compressed sensing yields 20% normalized mean squared error. We also show that at low SNR (25% noise compared to maximum signal), our deep learning model has less than 8% normalized mean squared error for quantitation of L-COSY spectra. These pilot simulation results appear promising and may help improve the efficiency and accuracy of L-COSY experiments in the future.

Published

2021

2. Deep learning can accelerate and quantify simulated localized correlated spectroscopy

Author

Iqbal, Zohaib, Iqbal, Zohaib, Nguyen, Dan, Thomas, Michael Albert, Jiang, Steve, Iqbal, Zohaib, Iqbal, Zohaib, Nguyen, Dan, Thomas, Michael Albert, and Jiang, Steve

Abstract

Nuclear magnetic resonance spectroscopy (MRS) allows for the determination of atomic structures and concentrations of different chemicals in a biochemical sample of interest. MRS is used in vivo clinically to aid in the diagnosis of several pathologies that affect metabolic pathways in the body. Typically, this experiment produces a one dimensional (1D) 1H spectrum containing several peaks that are well associated with biochemicals, or metabolites. However, since many of these peaks overlap, distinguishing chemicals with similar atomic structures becomes much more challenging. One technique capable of overcoming this issue is the localized correlated spectroscopy (L-COSY) experiment, which acquires a second spectral dimension and spreads overlapping signal across this second dimension. Unfortunately, the acquisition of a two dimensional (2D) spectroscopy experiment is extremely time consuming. Furthermore, quantitation of a 2D spectrum is more complex. Recently, artificial intelligence has emerged in the field of medicine as a powerful force capable of diagnosing disease, aiding in treatment, and even predicting treatment outcome. In this study, we utilize deep learning to: 1) accelerate the L-COSY experiment and 2) quantify L-COSY spectra. We demonstrate that our deep learning model greatly outperforms compressed sensing based reconstruction of L-COSY spectra at higher acceleration factors. Specifically, at four-fold acceleration, our method has less than 5% normalized mean squared error, whereas compressed sensing yields 20% normalized mean squared error. We also show that at low SNR (25% noise compared to maximum signal), our deep learning model has less than 8% normalized mean squared error for quantitation of L-COSY spectra. These pilot simulation results appear promising and may help improve the efficiency and accuracy of L-COSY experiments in the future.

Published

2021

3. Deep learning can accelerate and quantify simulated localized correlated spectroscopy.

Author

Iqbal, Zohaib, Iqbal, Zohaib, Nguyen, Dan, Thomas, Michael Albert, Jiang, Steve, Iqbal, Zohaib, Iqbal, Zohaib, Nguyen, Dan, Thomas, Michael Albert, and Jiang, Steve

Abstract

Nuclear magnetic resonance spectroscopy (MRS) allows for the determination of atomic structures and concentrations of different chemicals in a biochemical sample of interest. MRS is used in vivo clinically to aid in the diagnosis of several pathologies that affect metabolic pathways in the body. Typically, this experiment produces a one dimensional (1D) 1H spectrum containing several peaks that are well associated with biochemicals, or metabolites. However, since many of these peaks overlap, distinguishing chemicals with similar atomic structures becomes much more challenging. One technique capable of overcoming this issue is the localized correlated spectroscopy (L-COSY) experiment, which acquires a second spectral dimension and spreads overlapping signal across this second dimension. Unfortunately, the acquisition of a two dimensional (2D) spectroscopy experiment is extremely time consuming. Furthermore, quantitation of a 2D spectrum is more complex. Recently, artificial intelligence has emerged in the field of medicine as a powerful force capable of diagnosing disease, aiding in treatment, and even predicting treatment outcome. In this study, we utilize deep learning to: (1) accelerate the L-COSY experiment and (2) quantify L-COSY spectra. All training and testing samples were produced using simulated metabolite spectra for chemicals found in the human body. We demonstrate that our deep learning model greatly outperforms compressed sensing based reconstruction of L-COSY spectra at higher acceleration factors. Specifically, at four-fold acceleration, our method has less than 5% normalized mean squared error, whereas compressed sensing yields 20% normalized mean squared error. We also show that at low SNR (25% noise compared to maximum signal), our deep learning model has less than 8% normalized mean squared error for quantitation of L-COSY spectra. These pilot simulation results appear promising and may help improve the efficiency and accuracy of L-COSY experiment

Published

2021

4. Dictionary learning compressed sensing reconstruction: pilot validation of accelerated echo planar J-resolved spectroscopic imaging in prostate cancer.

Author

Joy, Ajin, Joy, Ajin, Nagarajan, Rajakumar, Saucedo, Andres, Iqbal, Zohaib, Sarma, Manoj K, Wilson, Neil, Felker, Ely, Reiter, Robert E, Raman, Steven S, Thomas, M Albert, Joy, Ajin, Joy, Ajin, Nagarajan, Rajakumar, Saucedo, Andres, Iqbal, Zohaib, Sarma, Manoj K, Wilson, Neil, Felker, Ely, Reiter, Robert E, Raman, Steven S, and Thomas, M Albert

Abstract

ObjectivesThis study aimed at developing dictionary learning (DL) based compressed sensing (CS) reconstruction for randomly undersampled five-dimensional (5D) MR Spectroscopic Imaging (3D spatial + 2D spectral) data acquired in prostate cancer patients and healthy controls, and test its feasibility at 8x and 12x undersampling factors.Materials and methodsProspectively undersampled 5D echo-planar J-resolved spectroscopic imaging (EP-JRESI) data were acquired in nine prostate cancer (PCa) patients and three healthy males. The 5D EP-JRESI data were reconstructed using DL and compared with gradient sparsity-based Total Variation (TV) and Perona-Malik (PM) methods. A hybrid reconstruction technique, Dictionary Learning-Total Variation (DLTV), was also designed to further improve the quality of reconstructed spectra.ResultsThe CS reconstruction of prospectively undersampled (8x and 12x) 5D EP-JRESI data acquired in prostate cancer and healthy subjects were performed using DL, DLTV, TV and PM. It is evident that the hybrid DLTV method can unambiguously resolve 2D J-resolved peaks including myo-inositol, citrate, creatine, spermine and choline.ConclusionImproved reconstruction of the accelerated 5D EP-JRESI data was observed using the hybrid DLTV. Accelerated acquisition of in vivo 5D data with as low as 8.33% samples (12x) corresponds to a total scan time of 14 min as opposed to a fully sampled scan that needs a total duration of 2.4 h (TR = 1.2 s, 32 [Formula: see text]×16 [Formula: see text]×8 [Formula: see text], 512 [Formula: see text] and 64 [Formula: see text]).

Published

2022

5. Dictionary learning compressed sensing reconstruction: pilot validation of accelerated echo planar J-resolved spectroscopic imaging in prostate cancer.

Author

Joy, Ajin, Joy, Ajin, Nagarajan, Rajakumar, Saucedo, Andres, Iqbal, Zohaib, Sarma, Manoj K, Wilson, Neil, Felker, Ely, Reiter, Robert E, Raman, Steven S, Thomas, M Albert, Joy, Ajin, Joy, Ajin, Nagarajan, Rajakumar, Saucedo, Andres, Iqbal, Zohaib, Sarma, Manoj K, Wilson, Neil, Felker, Ely, Reiter, Robert E, Raman, Steven S, and Thomas, M Albert

Abstract

ObjectivesThis study aimed at developing dictionary learning (DL) based compressed sensing (CS) reconstruction for randomly undersampled five-dimensional (5D) MR Spectroscopic Imaging (3D spatial + 2D spectral) data acquired in prostate cancer patients and healthy controls, and test its feasibility at 8x and 12x undersampling factors.Materials and methodsProspectively undersampled 5D echo-planar J-resolved spectroscopic imaging (EP-JRESI) data were acquired in nine prostate cancer (PCa) patients and three healthy males. The 5D EP-JRESI data were reconstructed using DL and compared with gradient sparsity-based Total Variation (TV) and Perona-Malik (PM) methods. A hybrid reconstruction technique, Dictionary Learning-Total Variation (DLTV), was also designed to further improve the quality of reconstructed spectra.ResultsThe CS reconstruction of prospectively undersampled (8x and 12x) 5D EP-JRESI data acquired in prostate cancer and healthy subjects were performed using DL, DLTV, TV and PM. It is evident that the hybrid DLTV method can unambiguously resolve 2D J-resolved peaks including myo-inositol, citrate, creatine, spermine and choline.ConclusionImproved reconstruction of the accelerated 5D EP-JRESI data was observed using the hybrid DLTV. Accelerated acquisition of in vivo 5D data with as low as 8.33% samples (12x) corresponds to a total scan time of 14 min as opposed to a fully sampled scan that needs a total duration of 2.4 h (TR = 1.2 s, 32 [Formula: see text]×16 [Formula: see text]×8 [Formula: see text], 512 [Formula: see text] and 64 [Formula: see text]).

Published

2022

6. Design and development of thyroxine/heparin releasing affordable cotton dressings to treat chronic wounds

Author

Waris, Tayyba Sher, Shah, Syed Tahir Abbas, Mehmood, Azra, Iqbal, Zohaib, Zehra, Mubashra, Chaudhry, Aqif Anwar, Rehman, Ihtesham Ur, Yar, Muhammad, Waris, Tayyba Sher, Shah, Syed Tahir Abbas, Mehmood, Azra, Iqbal, Zohaib, Zehra, Mubashra, Chaudhry, Aqif Anwar, Rehman, Ihtesham Ur, and Yar, Muhammad

Abstract

This research on a thyroxine/heparin-based cotton wound dressing tests angiogenic and wound healing ability of thyroxine/heparin in a chick chorionic allantoic membrane bioassay and in skin wounds in healthy rats. Commercially available cotton dressings were simply loaded with thyroxine/heparin solutions and coated with wax. Prior to undertaking the animal study, we assessed in vitro release of thyroxine/heparin from coated and uncoated cotton dressings. Both showed more than 85% release of drug over 14 days, though the lesser release was observed in wax-coated thyroxine/heparin dressing as compared to uncoated thyroxine/heparin dressing. Testing of angiogenesis through CAM assay proved good angiogenic potential of heparin and thyroxin, but the thyroxine found more angiogenic than heparin. In animal study, full-thickness skin wounds of 20 mm diameter showed good healing in both heparin and thyroxine-treated groups. But the most striking result was seen in the thyroxine-treated group where thyroxine showed significant difference with heparin-treated group and completely healed the wounds in 23 days. Thus, the study suggest that thyroxine possesses greater angiogenic and wound healing potential than heparin, and the use of thyroxine/heparin-loaded wax-coated cotton dressing could be a cost-effective option for the management of chronic wounds.

Published

2022

7. Design and development of thyroxine/heparin releasing affordable cotton dressings to treat chronic wounds

Author

Waris, Tayyba Sher, Shah, Syed Tahir Abbas, Mehmood, Azra, Iqbal, Zohaib, Zehra, Mubashra, Chaudhry, Aqif Anwar, Rehman, Ihtesham Ur, Yar, Muhammad, Waris, Tayyba Sher, Shah, Syed Tahir Abbas, Mehmood, Azra, Iqbal, Zohaib, Zehra, Mubashra, Chaudhry, Aqif Anwar, Rehman, Ihtesham Ur, and Yar, Muhammad

Abstract

This research on a thyroxine/heparin-based cotton wound dressing tests angiogenic and wound healing ability of thyroxine/heparin in a chick chorionic allantoic membrane bioassay and in skin wounds in healthy rats. Commercially available cotton dressings were simply loaded with thyroxine/heparin solutions and coated with wax. Prior to undertaking the animal study, we assessed in vitro release of thyroxine/heparin from coated and uncoated cotton dressings. Both showed more than 85% release of drug over 14 days, though the lesser release was observed in wax-coated thyroxine/heparin dressing as compared to uncoated thyroxine/heparin dressing. Testing of angiogenesis through CAM assay proved good angiogenic potential of heparin and thyroxin, but the thyroxine found more angiogenic than heparin. In animal study, full-thickness skin wounds of 20 mm diameter showed good healing in both heparin and thyroxine-treated groups. But the most striking result was seen in the thyroxine-treated group where thyroxine showed significant difference with heparin-treated group and completely healed the wounds in 23 days. Thus, the study suggest that thyroxine possesses greater angiogenic and wound healing potential than heparin, and the use of thyroxine/heparin-loaded wax-coated cotton dressing could be a cost-effective option for the management of chronic wounds.

Published

2022

8. Synthesis and application of titanium dioxide nanoparticles on cotton fabrics for UV protection

Author

Azeem, Abdul, Abid, Sharjeel, Sarwar, Zahid, Iqbal, Zohaib, Khalid, Faheem, Haseeb, Muhammad, Faheem, Sajid, Hussain, Tanveer, Munir, Usman, Saleem, Muhammad, Azeem, Abdul, Abid, Sharjeel, Sarwar, Zahid, Iqbal, Zohaib, Khalid, Faheem, Haseeb, Muhammad, Faheem, Sajid, Hussain, Tanveer, Munir, Usman, and Saleem, Muhammad

Abstract

In recent years, the requirements for the sun protection has increased dramatically with climate change specially in high UV index regions. This study was carried out to examine, test and enhance the ultraviolet protection of cotton fabric after applying titanium dioxide nanoparticles. Samples with different concentration of titanium dioxide nanoparticles were prepared by pad-dry- cure method and used in multiple test settings which investigated the presence and effectiveness of applied nanoparticles on fabric. Scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), X-Ray diffraction (XRD), ultraviolet protection and tensile strength were used to investigate the resultant effect. The results demonstrated that titanium dioxide nanoparticles showed effective resistance against ultraviolet rays and provided excellent ultraviolet protection while, little increase in tensile strength of treated fabric was observed.

Published

2020

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

Author

Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, Thomas, M Albert, Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, and Thomas, M Albert

Abstract

1H 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

10. Evaluation of Human Brain Metabolism using Five-Dimensional Echo Planar J-resolved Spectroscopic Imaging and Covariance J-resolved Spectroscopy

Author

Iqbal, Zohaib, Thomas, Michael A1, Iqbal, Zohaib, Iqbal, Zohaib, Thomas, Michael A1, and Iqbal, Zohaib

Abstract

Magnetic resonance spectroscopy (MRS) is a non-invasive tool capable of assessing metabolic changes in vivo. Point-resolved spectroscopy (PRESS) is a single-voxel based method which yields a one dimensional (1D) spectrum from a volume of interest, and is typically used to monitor metabolites in the brain. Several improvements have been added to this technique to enhance metabolite detection, one of which includes the addition of a second spectral dimension capable of encoding the J values of metabolites, known as J-resolved spectroscopy (JPRESS). Utilizing non-uniform sampling and compressed sensing methods, it is even possible to obtain these two dimensional (2D) spectra from multiple spatial dimensions, giving rise to accelerated J-resolved spectroscopic imaging (JRESI) techniques. This work presents novel processing and quantitation techniques capable of further enhancing the applications of both the JPRESS and JRESI methods. For JPRESS, a technique incorporating the covariance transformation is used to greatly improve spectral resolution in the indirect dimension. For JRESI, novel processing methods are used to quantify Glutamate, a prominent neurotransmitter in the brain, and other neuro-metabolites.

Published

2017

11. Evaluation of Human Brain Metabolism using Five-Dimensional Echo Planar J-resolved Spectroscopic Imaging and Covariance J-resolved Spectroscopy

Author

Iqbal, Zohaib, Thomas, Michael A1, Iqbal, Zohaib, Iqbal, Zohaib, Thomas, Michael A1, and Iqbal, Zohaib

Abstract

Magnetic resonance spectroscopy (MRS) is a non-invasive tool capable of assessing metabolic changes in vivo. Point-resolved spectroscopy (PRESS) is a single-voxel based method which yields a one dimensional (1D) spectrum from a volume of interest, and is typically used to monitor metabolites in the brain. Several improvements have been added to this technique to enhance metabolite detection, one of which includes the addition of a second spectral dimension capable of encoding the J values of metabolites, known as J-resolved spectroscopy (JPRESS). Utilizing non-uniform sampling and compressed sensing methods, it is even possible to obtain these two dimensional (2D) spectra from multiple spatial dimensions, giving rise to accelerated J-resolved spectroscopic imaging (JRESI) techniques. This work presents novel processing and quantitation techniques capable of further enhancing the applications of both the JPRESS and JRESI methods. For JPRESS, a technique incorporating the covariance transformation is used to greatly improve spectral resolution in the indirect dimension. For JRESI, novel processing methods are used to quantify Glutamate, a prominent neurotransmitter in the brain, and other neuro-metabolites.

Published

2017

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

Author

Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, Thomas, M Albert, Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, and Thomas, M Albert

Abstract

1H 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

13. Evaluation of Human Brain Metabolism using Five-Dimensional Echo Planar J-resolved Spectroscopic Imaging and Covariance J-resolved Spectroscopy

Author

Iqbal, Zohaib, Thomas, Michael A1, Iqbal, Zohaib, Iqbal, Zohaib, Thomas, Michael A1, and Iqbal, Zohaib

Abstract

Magnetic resonance spectroscopy (MRS) is a non-invasive tool capable of assessing metabolic changes in vivo. Point-resolved spectroscopy (PRESS) is a single-voxel based method which yields a one dimensional (1D) spectrum from a volume of interest, and is typically used to monitor metabolites in the brain. Several improvements have been added to this technique to enhance metabolite detection, one of which includes the addition of a second spectral dimension capable of encoding the J values of metabolites, known as J-resolved spectroscopy (JPRESS). Utilizing non-uniform sampling and compressed sensing methods, it is even possible to obtain these two dimensional (2D) spectra from multiple spatial dimensions, giving rise to accelerated J-resolved spectroscopic imaging (JRESI) techniques. This work presents novel processing and quantitation techniques capable of further enhancing the applications of both the JPRESS and JRESI methods. For JPRESS, a technique incorporating the covariance transformation is used to greatly improve spectral resolution in the indirect dimension. For JRESI, novel processing methods are used to quantify Glutamate, a prominent neurotransmitter in the brain, and other neuro-metabolites.

Published

2017

14. 3D spatially encoded and accelerated TE-averaged echo planar spectroscopic imaging in healthy human brain.

Author

Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, Thomas, M Albert, Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, and Thomas, M Albert

Abstract

Several different pathologies, including many neurodegenerative disorders, affect the energy metabolism of the brain. Glutamate, a neurotransmitter in the brain, can be used as a biomarker to monitor these metabolic processes. One method that is capable of quantifying glutamate concentration reliably in several regions of the brain is TE-averaged (1) H spectroscopic imaging. However, this type of method requires the acquisition of multiple TE lines, resulting in long scan durations. The goal of this experiment was to use non-uniform sampling, compressed sensing reconstruction and an echo planar readout gradient to reduce the scan time by a factor of eight to acquire TE-averaged spectra in three spatial dimensions. Simulation of glutamate and glutamine showed that the 2.2-2.4 ppm spectral region contained 95% glutamate signal using the TE-averaged method. Peak integration of this spectral range and home-developed, prior-knowledge-based fitting were used for quantitation. Gray matter brain phantom measurements were acquired on a Siemens 3 T Trio scanner. Non-uniform sampling was applied retrospectively to these phantom measurements and quantitative results of glutamate with respect to creatine 3.0 (Glu/Cr) ratios showed a coefficient of variance of 16% for peak integration and 9% for peak fitting using eight-fold acceleration. In vivo scans of the human brain were acquired as well and five different brain regions were quantified using the prior-knowledge-based algorithm. Glu/Cr ratios from these regions agreed with previously reported results in the literature. The method described here, called accelerated TE-averaged echo planar spectroscopic imaging (TEA-EPSI), is a significant methodological advancement and may be a useful tool for categorizing glutamate changes in pathologies where affected brain regions are not known a priori. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016

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

Author

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

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

Published

2016

16. 3D spatially encoded and accelerated TE-averaged echo planar spectroscopic imaging in healthy human brain.

Author

Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, Thomas, M Albert, Iqbal, Zohaib, Iqbal, Zohaib, Wilson, Neil E, and Thomas, M Albert

Abstract

Several different pathologies, including many neurodegenerative disorders, affect the energy metabolism of the brain. Glutamate, a neurotransmitter in the brain, can be used as a biomarker to monitor these metabolic processes. One method that is capable of quantifying glutamate concentration reliably in several regions of the brain is TE-averaged (1) H spectroscopic imaging. However, this type of method requires the acquisition of multiple TE lines, resulting in long scan durations. The goal of this experiment was to use non-uniform sampling, compressed sensing reconstruction and an echo planar readout gradient to reduce the scan time by a factor of eight to acquire TE-averaged spectra in three spatial dimensions. Simulation of glutamate and glutamine showed that the 2.2-2.4 ppm spectral region contained 95% glutamate signal using the TE-averaged method. Peak integration of this spectral range and home-developed, prior-knowledge-based fitting were used for quantitation. Gray matter brain phantom measurements were acquired on a Siemens 3 T Trio scanner. Non-uniform sampling was applied retrospectively to these phantom measurements and quantitative results of glutamate with respect to creatine 3.0 (Glu/Cr) ratios showed a coefficient of variance of 16% for peak integration and 9% for peak fitting using eight-fold acceleration. In vivo scans of the human brain were acquired as well and five different brain regions were quantified using the prior-knowledge-based algorithm. Glu/Cr ratios from these regions agreed with previously reported results in the literature. The method described here, called accelerated TE-averaged echo planar spectroscopic imaging (TEA-EPSI), is a significant methodological advancement and may be a useful tool for categorizing glutamate changes in pathologies where affected brain regions are not known a priori. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016

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

Author

Iqbal, Zohaib, Lundberg, Peter1, Iqbal, Zohaib, Wilson, Neil E, Keller, Margaret A, Michalik, David E, Church, Joseph A, Nielsen-Saines, Karin, Deville, Jaime, Souza, Raissa, Brecht, Mary-Lynn, Thomas, M Albert, Iqbal, Zohaib, Lundberg, Peter1, 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

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

Published

2016

18. Three-Dimensional Radiotherapy Dose Prediction on Head and Neck Cancer Patients with a Hierarchically Densely Connected U-net Deep Learning Architecture

Author

Nguyen, Dan, Jia, Xun, Sher, David, Lin, Mu-Han, Iqbal, Zohaib, Liu, Hui, Jiang, Steve, Nguyen, Dan, Jia, Xun, Sher, David, Lin, Mu-Han, Iqbal, Zohaib, Liu, Hui, and Jiang, Steve

Abstract

The treatment planning process for patients with head and neck (H&N) cancer is regarded as one of the most complicated due to large target volume, multiple prescription dose levels, and many radiation-sensitive critical structures near the target. Treatment planning for this site requires a high level of human expertise and a tremendous amount of effort to produce personalized high quality plans, taking as long as a week, which deteriorates the chances of tumor control and patient survival. To solve this problem, we propose to investigate a deep learning-based dose prediction model, Hierarchically Densely Connected U-net, based on two highly popular network architectures: U-net and DenseNet. We find that this new architecture is able to accurately and efficiently predict the dose distribution, outperforming the other two models, the Standard U-net and DenseNet, in homogeneity, dose conformity, and dose coverage on the test data. Averaging across all organs at risk, our proposed model is capable of predicting the organ-at-risk max dose within 6.3% and mean dose within 5.1% of the prescription dose on the test data. The other models, the Standard U-net and DenseNet, performed worse, having an averaged organ-at-risk max dose prediction error of 8.2% and 9.3%, respectively, and averaged mean dose prediction error of 6.4% and 6.8%, respectively. In addition, our proposed model used 12 times less trainable parameters than the Standard U-net, and predicted the patient dose 4 times faster than DenseNet.

Published

2018

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

Author

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

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

20. Echo-Planar J-resolved Spectroscopic Imaging using Dual Read-outs: Implementation and Quantitation of Human Brain Metabolites.

Author

Sarma, Manoj K, Sarma, Manoj K, Nagarajan, Rajakumar, Iqbal, Zohaib, Macey, Paul M, Thomas, M Albert, Sarma, Manoj K, Sarma, Manoj K, Nagarajan, Rajakumar, Iqbal, Zohaib, Macey, Paul M, and Thomas, M Albert

Abstract

Attempts have been made to reduce the total scan time in multi-dimensional J-resolved spectroscopic imaging (JRESI) using an echo-planar (EP) readout gradient, but acquisition duration remains a limitation for routine clinical use in the brain. We present here a significant acceleration achieved with a 4D EP-JRESI sequence that collects dual phase encoded lines within a single repetition time (TR) using two bipolar read-out trains. The performance and reliability of this novel 4D sequence, called Multi-Echo based Echo-Planar J-resolved Spectroscopic Imaging (ME-EP-JRESI), was evaluated in 10 healthy controls and a brain phantom using a 3 T MRI/MRS scanner. The prior knowledge fitting (ProFit) algorithm, with a new simulated basis set consisting of macromolecules and lipids apart from metabolites of interest, was used for quantitation. Both phantom and in-vivo data demonstrated that localization and spatial/spectral profiles of metabolites from the ME-EP-JRESI sequence were in good agreement with that of the EP-JRESI sequence. Both in the occipital and temporal lobe, metabolites with higher physiological concentrations including Glx (Glu+Gln), tNAA (NAA+NAAG), mI all had coefficient of variations between 9-25%. In summary, we have implemented, validated and tested the ME-EP-JRESI sequence, demonstrating that multi-echo acquisition can successfully reduce the total scan duration for EP-JRESI sequences.

Published

2017

21. Echo-Planar J-resolved Spectroscopic Imaging using Dual Read-outs: Implementation and Quantitation of Human Brain Metabolites.

Author

Sarma, Manoj K, Sarma, Manoj K, Nagarajan, Rajakumar, Iqbal, Zohaib, Macey, Paul M, Thomas, M Albert, Sarma, Manoj K, Sarma, Manoj K, Nagarajan, Rajakumar, Iqbal, Zohaib, Macey, Paul M, and Thomas, M Albert

Abstract

Attempts have been made to reduce the total scan time in multi-dimensional J-resolved spectroscopic imaging (JRESI) using an echo-planar (EP) readout gradient, but acquisition duration remains a limitation for routine clinical use in the brain. We present here a significant acceleration achieved with a 4D EP-JRESI sequence that collects dual phase encoded lines within a single repetition time (TR) using two bipolar read-out trains. The performance and reliability of this novel 4D sequence, called Multi-Echo based Echo-Planar J-resolved Spectroscopic Imaging (ME-EP-JRESI), was evaluated in 10 healthy controls and a brain phantom using a 3 T MRI/MRS scanner. The prior knowledge fitting (ProFit) algorithm, with a new simulated basis set consisting of macromolecules and lipids apart from metabolites of interest, was used for quantitation. Both phantom and in-vivo data demonstrated that localization and spatial/spectral profiles of metabolites from the ME-EP-JRESI sequence were in good agreement with that of the EP-JRESI sequence. Both in the occipital and temporal lobe, metabolites with higher physiological concentrations including Glx (Glu+Gln), tNAA (NAA+NAAG), mI all had coefficient of variations between 9-25%. In summary, we have implemented, validated and tested the ME-EP-JRESI sequence, demonstrating that multi-echo acquisition can successfully reduce the total scan duration for EP-JRESI sequences.

Published

2017

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

Author

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

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

23. Accurate Real Time Localization Tracking in A Clinical Environment using Bluetooth Low Energy and Deep Learning

Author

Iqbal, Zohaib, Luo, Da, Henry, Peter, Kazemifar, Samaneh, Rozario, Timothy, Yan, Yulong, Westover, Kenneth, Lu, Weiguo, Nguyen, Dan, Long, Troy, Wang, Jing, Choy, Hak, Jiang, Steve, Iqbal, Zohaib, Luo, Da, Henry, Peter, Kazemifar, Samaneh, Rozario, Timothy, Yan, Yulong, Westover, Kenneth, Lu, Weiguo, Nguyen, Dan, Long, Troy, Wang, Jing, Choy, Hak, and Jiang, Steve

Abstract

Deep learning has started to revolutionize several different industries, and the applications of these methods in medicine are now becoming more commonplace. This study focuses on investigating the feasibility of tracking patients and clinical staff wearing Bluetooth Low Energy (BLE) tags in a radiation oncology clinic using artificial neural networks (ANNs) and convolutional neural networks (CNNs). The performance of these networks was compared to relative received signal strength indicator (RSSI) thresholding and triangulation. By utilizing temporal information, a combined CNN+ANN network was capable of correctly identifying the location of the BLE tag with an accuracy of 99.9%. It outperformed a CNN model (accuracy = 94%), a thresholding model employing majority voting (accuracy = 95%), and a triangulation classifier utilizing majority voting (accuracy = 95%). Future studies will seek to deploy this affordable real time location system in hospitals to improve clinical workflow, efficiency, and patient safety.

Published

2017

24. A feasibility study for predicting optimal radiation therapy dose distributions of prostate cancer patients from patient anatomy using deep learning

Author

Nguyen, Dan, Long, Troy, Jia, Xun, Lu, Weiguo, Gu, Xuejun, Iqbal, Zohaib, Jiang, Steve, Nguyen, Dan, Long, Troy, Jia, Xun, Lu, Weiguo, Gu, Xuejun, Iqbal, Zohaib, and Jiang, Steve

Abstract

With the advancement of treatment modalities in radiation therapy for cancer patients, outcomes have improved, but at the cost of increased treatment plan complexity and planning time. The accurate prediction of dose distributions would alleviate this issue by guiding clinical plan optimization to save time and maintain high quality plans. We have modified a convolutional deep network model, U-net (originally designed for segmentation purposes), for predicting dose from patient image contours of the planning target volume (PTV) and organs at risk (OAR). We show that, as an example, we are able to accurately predict the dose of intensity-modulated radiation therapy (IMRT) for prostate cancer patients, where the average Dice similarity coefficient is 0.91 when comparing the predicted vs. true isodose volumes between 0% and 100% of the prescription dose. The average value of the absolute differences in [max, mean] dose is found to be under 5% of the prescription dose, specifically for each structure is [1.80%, 1.03%](PTV), [1.94%, 4.22%](Bladder), [1.80%, 0.48%](Body), [3.87%, 1.79%](L Femoral Head), [5.07%, 2.55%](R Femoral Head), and [1.26%, 1.62%](Rectum) of the prescription dose. We thus managed to map a desired radiation dose distribution from a patient's PTV and OAR contours. As an additional advantage, relatively little data was used in the techniques and models described in this paper.

Published

2017

25. 2-D MR Spectroscopy Combined with 2-D/3-D Spatial Encoding

Author

Thomas, M Albert, Thomas, M Albert, Iqbal, Zohaib, Sarma, Manoj K, Nagarajan, Rajakumar, Macey, Paul M, Huda, Amir, Thomas, M Albert, Thomas, M Albert, Iqbal, Zohaib, Sarma, Manoj K, Nagarajan, Rajakumar, Macey, Paul M, and Huda, Amir

Published

2016

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

Author

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

Abstract

PurposeTo 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.MethodsAn 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.ResultsRetrospective 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.ConclusionBy 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.

Published

2016

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

Author

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

Abstract

PurposeTo 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.MethodsAn 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.ResultsRetrospective 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.ConclusionBy 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.

Published

2016

28. 2-D MR Spectroscopy Combined with 2-D/3-D Spatial Encoding

Author

Thomas, M Albert, Thomas, M Albert, Iqbal, Zohaib, Sarma, Manoj K, Nagarajan, Rajakumar, Macey, Paul M, Huda, Amir, Thomas, M Albert, Thomas, M Albert, Iqbal, Zohaib, Sarma, Manoj K, Nagarajan, Rajakumar, Macey, Paul M, and Huda, Amir

Published

2016

29. Accelerated echo planar J-resolved spectroscopic imaging in prostate cancer: a pilot validation of non-linear reconstruction using total variation and maximum entropy.

Author

Nagarajan, Rajakumar, Nagarajan, Rajakumar, Iqbal, Zohaib, Burns, Brian, Wilson, Neil E, Sarma, Manoj K, Margolis, Daniel A, Reiter, Robert E, Raman, Steven S, Thomas, M Albert, Nagarajan, Rajakumar, Nagarajan, Rajakumar, Iqbal, Zohaib, Burns, Brian, Wilson, Neil E, Sarma, Manoj K, Margolis, Daniel A, Reiter, Robert E, Raman, Steven S, and Thomas, M Albert

Abstract

The overlap of metabolites is a major limitation in one-dimensional (1D) spectral-based single-voxel MRS and multivoxel-based MRSI. By combining echo planar spectroscopic imaging (EPSI) with a two-dimensional (2D) J-resolved spectroscopic (JPRESS) sequence, 2D spectra can be recorded in multiple locations in a single slice of prostate using four-dimensional (4D) echo planar J-resolved spectroscopic imaging (EP-JRESI). The goal of the present work was to validate two different non-linear reconstruction methods independently using compressed sensing-based 4D EP-JRESI in prostate cancer (PCa): maximum entropy (MaxEnt) and total variation (TV). Twenty-two patients with PCa with a mean age of 63.8 years (range, 46-79 years) were investigated in this study. A 4D non-uniformly undersampled (NUS) EP-JRESI sequence was implemented on a Siemens 3-T MRI scanner. The NUS data were reconstructed using two non-linear reconstruction methods, namely MaxEnt and TV. Using both TV and MaxEnt reconstruction methods, the following observations were made in cancerous compared with non-cancerous locations: (i) higher mean (choline + creatine)/citrate metabolite ratios; (ii) increased levels of (choline + creatine)/spermine and (choline + creatine)/myo-inositol; and (iii) decreased levels of (choline + creatine)/(glutamine + glutamate). We have shown that it is possible to accelerate the 4D EP-JRESI sequence by four times and that the data can be reliably reconstructed using the TV and MaxEnt methods. The total acquisition duration was less than 13 min and we were able to detect and quantify several metabolites.

Published

2015

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

Author

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

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

31. Accelerated echo planar J-resolved spectroscopic imaging in prostate cancer: a pilot validation of non-linear reconstruction using total variation and maximum entropy.

Author

Nagarajan, Rajakumar, Nagarajan, Rajakumar, Iqbal, Zohaib, Burns, Brian, Wilson, Neil E, Sarma, Manoj K, Margolis, Daniel A, Reiter, Robert E, Raman, Steven S, Thomas, M Albert, Nagarajan, Rajakumar, Nagarajan, Rajakumar, Iqbal, Zohaib, Burns, Brian, Wilson, Neil E, Sarma, Manoj K, Margolis, Daniel A, Reiter, Robert E, Raman, Steven S, and Thomas, M Albert

Abstract

The overlap of metabolites is a major limitation in one-dimensional (1D) spectral-based single-voxel MRS and multivoxel-based MRSI. By combining echo planar spectroscopic imaging (EPSI) with a two-dimensional (2D) J-resolved spectroscopic (JPRESS) sequence, 2D spectra can be recorded in multiple locations in a single slice of prostate using four-dimensional (4D) echo planar J-resolved spectroscopic imaging (EP-JRESI). The goal of the present work was to validate two different non-linear reconstruction methods independently using compressed sensing-based 4D EP-JRESI in prostate cancer (PCa): maximum entropy (MaxEnt) and total variation (TV). Twenty-two patients with PCa with a mean age of 63.8 years (range, 46-79 years) were investigated in this study. A 4D non-uniformly undersampled (NUS) EP-JRESI sequence was implemented on a Siemens 3-T MRI scanner. The NUS data were reconstructed using two non-linear reconstruction methods, namely MaxEnt and TV. Using both TV and MaxEnt reconstruction methods, the following observations were made in cancerous compared with non-cancerous locations: (i) higher mean (choline + creatine)/citrate metabolite ratios; (ii) increased levels of (choline + creatine)/spermine and (choline + creatine)/myo-inositol; and (iii) decreased levels of (choline + creatine)/(glutamine + glutamate). We have shown that it is possible to accelerate the 4D EP-JRESI sequence by four times and that the data can be reliably reconstructed using the TV and MaxEnt methods. The total acquisition duration was less than 13 min and we were able to detect and quantify several metabolites.

Published

2015

32. UMTG: A Toolset to Automatically Generate System Test Cases from Use Case Specifications

Author

Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, Iqbal, Zohaib, Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, and Iqbal, Zohaib

Abstract

We present UMTG, a toolset for automatically generating executable and traceable system test cases from use case specifications. UMTG employs Natural Language Processing (NLP), a restricted form of use case specifications, and constraint solving. Use cases are expected to follow a template with restriction rules that reduce imprecision and enable NLP. NLP is used to capture the control flow implicitly described in use case specifications. Finally, to generate test input, constraint solving is applied to OCL constraints referring to the domain model of the system. UMTG is integrated with two tools that are widely adopted in industry, IBM Doors and Rhapsody. UMTG has been successfully evaluated on an industrial case study.

Published

2015

33. Automatic Generation of System Test Cases from Use Case Specifications

Author

Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Fonds National de la Recherche - FnR [sponsor], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, Iqbal, Zohaib, Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Fonds National de la Recherche - FnR [sponsor], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, and Iqbal, Zohaib

Abstract

In safety critical domains, system test cases are often derived from functional requirements in natural language (NL) and traceability between requirements and their corresponding test cases is usually mandatory. The definition of test cases is therefore time-consuming and error prone, especially so given the quickly rising complexity of embedded systems in many critical domains. Though considerable research has been devoted to automatic generation of system test cases from NL requirements, most of the proposed approaches re- quire significant manual intervention or additional, complex behavioral modelling. This significantly hinders their appli- cability in practice. In this paper, we propose Use Case Modelling for System Tests Generation (UMTG), an approach that automatically generates executable system test cases from use case spec- ifications and a domain model, the latter including a class diagram and constraints. Our rationale and motivation are that, in many environments, including that of our industry partner in the reported case study, both use case specifica- tions and domain modelling are common and accepted prac- tice, whereas behavioural modelling is considered a difficult and expensive exercise if it is to be complete and precise. In order to extract behavioral information from use cases and enable test automation, UMTG employs Natural Language Processing (NLP), a restricted form of use case specifica- tions, and constraint solving.

Published

2015

34. Automatic Generation of System Test Cases from Use Case Specifications

Author

Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Fonds National de la Recherche - FnR [sponsor], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, Iqbal, Zohaib, Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Fonds National de la Recherche - FnR [sponsor], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, and Iqbal, Zohaib

Abstract

In safety critical domains, system test cases are often derived from functional requirements in natural language (NL) and traceability between requirements and their corresponding test cases is usually mandatory. The definition of test cases is therefore time-consuming and error prone, especially so given the quickly rising complexity of embedded systems in many critical domains. Though considerable research has been devoted to automatic generation of system test cases from NL requirements, most of the proposed approaches re- quire significant manual intervention or additional, complex behavioral modelling. This significantly hinders their appli- cability in practice. In this paper, we propose Use Case Modelling for System Tests Generation (UMTG), an approach that automatically generates executable system test cases from use case spec- ifications and a domain model, the latter including a class diagram and constraints. Our rationale and motivation are that, in many environments, including that of our industry partner in the reported case study, both use case specifica- tions and domain modelling are common and accepted prac- tice, whereas behavioural modelling is considered a difficult and expensive exercise if it is to be complete and precise. In order to extract behavioral information from use cases and enable test automation, UMTG employs Natural Language Processing (NLP), a restricted form of use case specifica- tions, and constraint solving.

Published

2015

35. UMTG: A Toolset to Automatically Generate System Test Cases from Use Case Specifications

Author

Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, Iqbal, Zohaib, Interdisciplinary Centre for Security, Reliability and Trust (SnT) > Software Verification and Validation Lab (SVV Lab) [research center], Wang, Chunhui, Pastore, Fabrizio, Göknil, Arda, Briand, Lionel, and Iqbal, Zohaib

Abstract

We present UMTG, a toolset for automatically generating executable and traceable system test cases from use case specifications. UMTG employs Natural Language Processing (NLP), a restricted form of use case specifications, and constraint solving. Use cases are expected to follow a template with restriction rules that reduce imprecision and enable NLP. NLP is used to capture the control flow implicitly described in use case specifications. Finally, to generate test input, constraint solving is applied to OCL constraints referring to the domain model of the system. UMTG is integrated with two tools that are widely adopted in industry, IBM Doors and Rhapsody. UMTG has been successfully evaluated on an industrial case study.

Published

2015

36. Improving the Performance of OCL Constraint Solving with Novel Heuristics for Logical Operations: A SearchBased Approach

Author

Ali, Shaukat, Iqbal, Zohaib, Khalid, Maham, Arcuri, Andrea, Ali, Shaukat, Iqbal, Zohaib, Khalid, Maham, and Arcuri, Andrea

Abstract

A common practice to specify constraints on the Unified Modeling Language (UML) models is using the Object Constraint Language (OCL). Such constraints serve various purposes, ranging from simply providing precise meaning to the models to supporting complex verification and validation activities. In many applications, these constraints have to be solved to obtain values satisfying the constraints, for example, in the case of modelbased testing (MBT) to generate test data for the purpose of generating executable test cases. In our previous work, we proposed novel heuristics for various OCL constructs to efficiently solve them using search algorithms. These heuristics are enhanced in this paper to further improve the performance of OCL constraint solving. We performed an empirical evaluation comprising of three case studies using three search algorithms: Alternating Variable Method (AVM), (1+1) Evolutionary Algorithm (EA), and a Genetic Algorithm (GA) and in addition Random Search (RS) was used as a comparison baseline. In the first case study, we evaluated each heuristics using carefully designed artificial problems. In the second case study, we evaluated the heuristics on various constraints of Cisco’s Video Conferencing Systems defined to support MBT. Finally, the third case study is about EURent Car Rental specification and is obtained from the literature. The results of the empirical evaluation showed that (1+1) EA and AVM with the improved heuristics significantly outperform the rest of the algorithms.

Published

2015

37. Improving the Performance of OCL Constraint Solving with Novel Heuristics for Logical Operations: A SearchBased Approach

Author

Ali, Shaukat, Iqbal, Zohaib, Khalid, Maham, Arcuri, Andrea, Ali, Shaukat, Iqbal, Zohaib, Khalid, Maham, and Arcuri, Andrea

Abstract

A common practice to specify constraints on the Unified Modeling Language (UML) models is using the Object Constraint Language (OCL). Such constraints serve various purposes, ranging from simply providing precise meaning to the models to supporting complex verification and validation activities. In many applications, these constraints have to be solved to obtain values satisfying the constraints, for example, in the case of modelbased testing (MBT) to generate test data for the purpose of generating executable test cases. In our previous work, we proposed novel heuristics for various OCL constructs to efficiently solve them using search algorithms. These heuristics are enhanced in this paper to further improve the performance of OCL constraint solving. We performed an empirical evaluation comprising of three case studies using three search algorithms: Alternating Variable Method (AVM), (1+1) Evolutionary Algorithm (EA), and a Genetic Algorithm (GA) and in addition Random Search (RS) was used as a comparison baseline. In the first case study, we evaluated each heuristics using carefully designed artificial problems. In the second case study, we evaluated the heuristics on various constraints of Cisco’s Video Conferencing Systems defined to support MBT. Finally, the third case study is about EURent Car Rental specification and is obtained from the literature. The results of the empirical evaluation showed that (1+1) EA and AVM with the improved heuristics significantly outperform the rest of the algorithms.

Published

2015

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

Author

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

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

39. Applying UML/MARTE on industrial projects: challenges, experiences, and guidelines

Author

Iqbal, Zohaib, Ali, Shaukat, Yue, Tao, Briand, Lionel, Iqbal, Zohaib, Ali, Shaukat, Yue, Tao, and Briand, Lionel

Published

2014

40. Applying UML/MARTE on industrial projects: challenges, experiences, and guidelines

Author

Iqbal, Zohaib, Ali, Shaukat, Yue, Tao, Briand, Lionel, Iqbal, Zohaib, Ali, Shaukat, Yue, Tao, and Briand, Lionel

Published

2014

41. Generating Test Data from OCL Constraints with Search Techniques

Author

Ali, Shaukat, Iqbal, Zohaib, Arcuri, Andrea, Briand, Lionel, Ali, Shaukat, Iqbal, Zohaib, Arcuri, Andrea, and Briand, Lionel

Published

2013

42. Generating Test Data from OCL Constraints with Search Techniques

Author

Ali, Shaukat, Iqbal, Zohaib, Arcuri, Andrea, Briand, Lionel, Ali, Shaukat, Iqbal, Zohaib, Arcuri, Andrea, and Briand, Lionel

Published

2013