Baraa Al-Hafez scite author profile

Sympathetic hyperinnervation occurs in human ventricular tissue after myocardial infarction and may contribute to arrhythmias. Aberrant sympathetic sprouting is associated with elevated nerve growth factor (NGF) in many contexts, including ventricular hyperinnervation. However, it is unclear whether cardiomyocytes or other cell types are responsible for increased NGF synthesis. In this study, left coronary arteries were ligated and ventricular tissue examined in rats 1-28 days post-infarction. Infarct and peri-infarct tissue was essentially devoid of sensory and parasympathetic nerves at all time points. However, areas of increased sympathetic nerve density were observed in the peri-infarct zone between post-ligation days 4-14. Hyperinnervation occurred in regions containing accumulations of macrophages and myofibroblasts. To assess whether these inflammatory cells synthesize NGF, sections were processed for NGF in situ hybridization and immunohistochemistry. Both macrophage1 antigen-positive macrophages and α-smooth muscle actin immunoreactive myofibroblasts expressed NGF in areas where they were closely proximate to sympathetic nerves. To investigate whether NGF produced by peri-infarct cells induces sympathetic outgrowth, we cocultured adult sympathetic ganglia with peri-infarct explants. Neurite outgrowth from sympathetic ganglia was significantly greater at post-ligation days 7-14 as compared to control tissue. Addition of an NGF function-blocking antibody prevented the increased neurite outgrowth induced by periinfarct tissue. These findings provide evidence that inflammatory cell NGF synthesis plays a causal role in sympathetic hyperinnervation following myocardial infarction.

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A mouse model of sensorimotor controlled cortical impact: Characterization using longitudinal magnetic resonance imaging, behavioral assessments and histology

Onyszchuk

Al-Hafez

et al. 2007

Journal of Neuroscience Methods

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The present study establishes a new mouse model for traumatic brain injury (TBI), using an electromechanically driven linear motor impactor device to deliver a lateral controlled cortical impact (CCI) injury to the sensorimotor cortex. Lesion cavity size was measured, and inter-animal consistency demonstrated, at 14 days post injury. Qualitative information regarding damage progression over time was obtained by scanning with high field magnetic resonance imaging (MRI) at five time points following injury. Functional impairment and recovery were measured with the Rotarod, gridwalk and cylinder tests, and lesion cavity volume was measured post mortem with thionin-stained tissue sections. The study establishes the reliability of a linear-motor based device for producing repeatable damage in a CCI model, demonstrates the power of longitudinal MRI in studying damage evolution, and confirms that a simple battery of functional tests record sensorimotor impairment and recovery.

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Characterization of Alterations in Diabetic Myocardial Tissue Using High Resolution MRI

Loganathan

Bilgen

Al-Hafez

et al. 2005

Int J Cardiovasc Imaging

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Cardiovascular complications, including diabetic cardiomyopathy, are the major cause of fatalities in diabetes. Diabetic cardiomyopathy is expressed in part through fibrosis and left ventricular hypertrophy, increasing myocardial stiffness leading to heart failure. In order to search for curative interventions, precise evaluation of the diabetic heart pathology is extremely important. Magnetic resonance imaging (MRI) is ideally suited for the assessment of heart disorders due to its high resolution, three-dimensional properties and dimensional accuracy. In this study streptozotocin injected Sprague-Dawley rats were used as a model of type 1 diabetes to characterize abnormalities in the diabetic left ventricle (LV). High resolution MRI using a 9.4 T horizontal bore scanner was performed on control and 7 weeks diabetic rats. In the diabetic rats as compared to controls, we found increased LV wall volume to body weight ratio, suggestive of LV hypertrophy; increased LV wall mean pixel intensity, and decreased T2 relaxation time, both suggestive of changes in the diabetic tissue properties, perhaps due to presence of fibrosis which was detected through increase in the collagen fractional area. In addition, changes in the LV cavity area were observed and quantified in post-mortem diabetic hearts indicative of stiffer and less resilient LV myocardial tissue with diabetes. Together the data suggest that LV hypertrophy and fibrosis may be a major factor underlying structural and functional abnormalities in the diabetic heart, and MRI is a valuable tool to non-invasively monitor the pathological changes in diabetic cardiomyopathy.

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Magnetic resonance imaging of mouse spinal cord

Bilgen¹,

Al-Hafez²,

Berman³

et al. 2005

Magnetic Resonance in Med

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The feasibility of performing high-resolution in vivo MRI on mouse spinal cord (SC) at 9.4 T magnetic field strength is demonstrated. The MR properties of the cord tissue were measured and the characteristics of water diffusion in the SC were quantified. The data indicate that the differences in the proton density (PD) and transverse relaxation time between gray matter (GM) and white matter (WM) dominate the contrast seen on the mouse SC images at 9.4 T. However, on heavily T(2)-weighted images these differences result in a reversal of contrast. The diffusion of water in the cord is anisotropic, but the WM exhibits greater anisotropy and principal diffusivity than the GM. The quantitative data presented here should establish a standard for comparing similar measurements obtained from the SCs of genetically engineered mouse or mouse models of SC injury (SCI).

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Exercise training improves cardiac performance in diabetes: in vivo demonstration with quantitative cine-MRI analyses

Loganathan

Bilgen²,

Al-Hafez³

et al. 2007

Journal of Applied Physiology

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Longitudinal magnetic resonance imaging of spinal cord injury in mouse: changes in signal patterns associated with the inflammatory response

Bilgen

Al-Hafez

Alrefae

et al. 2007

Magnetic Resonance Imaging

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Microneurography of human median nerve

Bilgen

Heddings

Al-Hafez

et al. 2005

Magnetic Resonance Imaging

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Purpose:To examine the possibility of performing highresolution MRI (microneurography) on peripheral nerves. Materials and Methods:A specific radio frequency (RF) coil was developed to probe the human median nerve at a magnetic field strength of 9.4 T and tested on three excised samples by acquiring microneurograms. Results:The microneurograms revealed neuronal tissue constituents at subfascicular level. The contrast features on proton-density and T1-and T2-weighted images were described and compared. The microscopic water movement was quantified using diffusion weighting parallel and orthogonal to the neuronal fiber orientation. The characteristics of anisotropic diffusion in the median nerve were comparable to those reported from other biological tissues (white matter and kidney). Conclusion:The results overall suggest that microneurography might provide new noninvasive insights into microscopic gross anatomy of the peripheral nerve, injury evaluation, and efficacy of repair, although the feasibility at current clinically relevant field strengths is yet to be determined.

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Cardiac dysfunction in the diabetic rat: quantitative evaluation using high resolution magnetic resonance imaging

Loganathan

Bilgen

Al-Hafez

et al. 2006

Cardiovasc Diabetol

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Baraa Al-Hafez

Sympathetic hyperinnervation and inflammatory cell NGF synthesis following myocardial infarction in rats

A mouse model of sensorimotor controlled cortical impact: Characterization using longitudinal magnetic resonance imaging, behavioral assessments and histology

Characterization of Alterations in Diabetic Myocardial Tissue Using High Resolution MRI

Magnetic resonance imaging of mouse spinal cord

Exercise training improves cardiac performance in diabetes: in vivo demonstration with quantitative cine-MRI analyses

Longitudinal magnetic resonance imaging of spinal cord injury in mouse: changes in signal patterns associated with the inflammatory response

Microneurography of human median nerve

Cardiac dysfunction in the diabetic rat: quantitative evaluation using high resolution magnetic resonance imaging

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