Your search keyword '"Diaz, Agustin"' showing total 3 results

1. Paraspinal muscle degeneration and regenerative potential in a Murine model of Lumbar Disc Injury.

Author

Davies, Michael R, Davies, Michael R, Kaur, Gurbani, Liu, Xuhui, Alvarado, Francisco Gomez, Nuthalapati, Prashant, Liu, Mengyao, Diaz, Agustin, Lotz, Jeffrey C, Bailey, Jeannie F, Feeley, Brian T, Davies, Michael R, Davies, Michael R, Kaur, Gurbani, Liu, Xuhui, Alvarado, Francisco Gomez, Nuthalapati, Prashant, Liu, Mengyao, Diaz, Agustin, Lotz, Jeffrey C, Bailey, Jeannie F, and Feeley, Brian T

Abstract

Background contextThe association between low back pain and lumbar disc degeneration is not fully characterized. One potentially overlooked factor of this process is the lumbar multifidus, which plays a role in segmental stabilization and locomotion. Previous reports have shown multifidus degeneration to be associated with disc degeneration. The goal of this study was to develop a mouse model of advanced lumbar disc degeneration to recapitulate the pathology of the human multifidus in patients with lumbar disc degeneration and low back pain.MethodsC57BL/6 mice underwent a left anterolateral approach to the lumbar spine and disc puncture with a micro scalpel at L5/6 and L6/S1. Mice underwent behavioral analysis and functional gait testing. A subset of mice underwent 14T T2-weighted MRI to assess disc degeneration and paraspinal muscle quality. At 6 and 15 weeks, mice were sacrificed, and the multifidus muscles were harvested and divided into proximal and distal segments relative to disc injury. Histological analysis was performed to assess muscle degeneration, fiber type, and macrophage density. Fibroadipogenic progenitors (FAPs) were isolated for gene expression analysis with qPCR.ResultsMRI demonstrated decreased intervertebral disc signal and paraspinal muscle atrophy at 6 weeks, with progressive degeneration and atrophy at 15 weeks. Disc injury resulted in delayed functional recovery and impaired gait. Histology demonstrated progressive multifidus fibrofatty degeneration between 6 and 15 weeks. CD68+ macrophage density was increased at 6 weeks but not 15 weeks. FAPs exhibited increased fibrotic and adipogenic gene expression at 6 weeks compared to sham with less of a difference in gene expression by 15 weeks.ConclusionsWe have developed a mouse model of disc injury-mediated paraspinal muscle degeneration that recapitulates features of degenerative muscle pathology observed in patients with lumbar disc degeneration, and highlights the role of FAPs in mediating fib

Published

2021

2. Paraspinal muscle degeneration and regenerative potential in a Murine model of Lumbar Disc Injury.

Author

Davies, Michael R, Davies, Michael R, Kaur, Gurbani, Liu, Xuhui, Alvarado, Francisco Gomez, Nuthalapati, Prashant, Liu, Mengyao, Diaz, Agustin, Lotz, Jeffrey C, Bailey, Jeannie F, Feeley, Brian T, Davies, Michael R, Davies, Michael R, Kaur, Gurbani, Liu, Xuhui, Alvarado, Francisco Gomez, Nuthalapati, Prashant, Liu, Mengyao, Diaz, Agustin, Lotz, Jeffrey C, Bailey, Jeannie F, and Feeley, Brian T

Abstract

Background contextThe association between low back pain and lumbar disc degeneration is not fully characterized. One potentially overlooked factor of this process is the lumbar multifidus, which plays a role in segmental stabilization and locomotion. Previous reports have shown multifidus degeneration to be associated with disc degeneration. The goal of this study was to develop a mouse model of advanced lumbar disc degeneration to recapitulate the pathology of the human multifidus in patients with lumbar disc degeneration and low back pain.MethodsC57BL/6 mice underwent a left anterolateral approach to the lumbar spine and disc puncture with a micro scalpel at L5/6 and L6/S1. Mice underwent behavioral analysis and functional gait testing. A subset of mice underwent 14T T2-weighted MRI to assess disc degeneration and paraspinal muscle quality. At 6 and 15 weeks, mice were sacrificed, and the multifidus muscles were harvested and divided into proximal and distal segments relative to disc injury. Histological analysis was performed to assess muscle degeneration, fiber type, and macrophage density. Fibroadipogenic progenitors (FAPs) were isolated for gene expression analysis with qPCR.ResultsMRI demonstrated decreased intervertebral disc signal and paraspinal muscle atrophy at 6 weeks, with progressive degeneration and atrophy at 15 weeks. Disc injury resulted in delayed functional recovery and impaired gait. Histology demonstrated progressive multifidus fibrofatty degeneration between 6 and 15 weeks. CD68+ macrophage density was increased at 6 weeks but not 15 weeks. FAPs exhibited increased fibrotic and adipogenic gene expression at 6 weeks compared to sham with less of a difference in gene expression by 15 weeks.ConclusionsWe have developed a mouse model of disc injury-mediated paraspinal muscle degeneration that recapitulates features of degenerative muscle pathology observed in patients with lumbar disc degeneration, and highlights the role of FAPs in mediating fib

Published

2021

3. Rotator cuff tear degeneration and the role of fibro-adipogenic progenitors.

Author

Agha, Obiajulu, Agha, Obiajulu, Diaz, Agustin, Davies, Michael, Kim, Hubert T, Liu, Xuhui, Feeley, Brian T, Agha, Obiajulu, Agha, Obiajulu, Diaz, Agustin, Davies, Michael, Kim, Hubert T, Liu, Xuhui, and Feeley, Brian T

Abstract

The high prevalence of rotator cuff tears poses challenges to individual patients and the healthcare system at large. This orthopedic injury is complicated further by high rates of retear after surgical repair. Outcomes following repair are highly dependent upon the quality of the injured rotator cuff muscles, and it is, therefore, crucial that the pathophysiology of rotator cuff degeneration continues to be explored. Fibro-adipogenic progenitors, a major population of resident muscle stem cells, have emerged as the main source of intramuscular fibrosis and fatty infiltration, both of which are key features of rotator cuff muscle degeneration. Improvements to rotator cuff repair outcomes will likely require addressing the muscle pathology produced by these cells. The aim of this review is to summarize the current rotator cuff degeneration assessment tools, the effects of poor muscle quality on patient outcomes, the role of fibro-adipogenic progenitors in mediating muscle pathology, and how these cells could be leveraged for potential therapeutics to augment current rotator cuff surgical and rehabilitative strategies.

Published

2021