Carlos A. Aguilar scite author profile

Skeletal muscle possesses a remarkable capacity to regenerate when injured, but when confronted with major traumatic injury resulting in volumetric muscle loss (VML), the regenerative process consistently fails. The loss of muscle tissue and function from VML injury has prompted development of a suite of therapeutic approaches but these strategies have proceeded without a comprehensive understanding of the molecular landscape that drives the injury response. Herein, we administered a VML injury in an established rodent model and monitored the evolution of the healing phenomenology over multiple time points using muscle function testing, histology, and expression profiling by RNA sequencing. The injury response was then compared to a regenerative medicine treatment using orthotopic transplantation of autologous minced muscle grafts (~1 mm3 tissue fragments). A chronic inflammatory and fibrotic response was observed at all time points following VML. These results suggest that the pathological response to VML injury during the acute stage of the healing response overwhelms endogenous and therapeutic regenerative processes. Overall, the data presented delineate key molecular characteristics of the pathobiological response to VML injury that are critical effectors of effective regenerative treatment paradigms.

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Resolvin D1 supports skeletal myofiber regeneration via actions on myeloid and muscle stem cells

Markworth¹,

Brown²,

Lim³

et al. 2020

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Unwavering Pathobiology of Volumetric Muscle Loss Injury

Greising

Rivera

Goldman

et al. 2017

Sci Rep

101

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Volumetric muscle loss (VML) resulting from extremity trauma presents chronic and persistent functional deficits which ultimately manifest disability. Acellular biological scaffolds, or decellularized extracellular matrices (ECMs), embody an ideal treatment platform due to their current clinical use for soft tissue repair, off-the-shelf availability, and zero autogenous donor tissue burden. ECMs have been reported to promote functional skeletal muscle tissue remodeling in small and large animal models of VML injury, and this conclusion was reached in a recent clinical trial that enrolled 13 patients. However, numerous other pre-clinical reports have not observed ECM-mediated skeletal muscle regeneration. The current study was designed to reconcile these discrepancies. The capacity of ECMs to orchestrate functional muscle tissue remodeling was interrogated in a porcine VML injury model using unbiased assessments of muscle tissue regeneration and functional recovery. Here, we show that VML injury incites an overwhelming inflammatory and fibrotic response that leads to expansive fibrous tissue deposition and chronic functional deficits, which ECM repair does not augment.

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Direct micro-patterning of biodegradable polymers using ultraviolet and femtosecond lasers

et al. 2005

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Dissecting Murine Muscle Stem Cell Aging through Regeneration Using Integrative Genomic Analysis

et al. 2020

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SUMMARY During aging, there is a progressive loss of volume and function in skeletal muscle that impacts mobility and quality of life. The repair of skeletal muscle is regulated by tissue-resident stem cells called satellite cells (or muscle stem cells [MuSCs]), but in aging, MuSCs decrease in numbers and regenerative capacity. The transcriptional networks and epigenetic changes that confer diminished regenerative function in MuSCs as a result of natural aging are only partially understood. Herein, we use an integrative genomics approach to profile MuSCs from young and aged animals before and after injury. Integration of these datasets reveals aging impacts multiple regulatory changes through significant differences in gene expression, metabolic flux, chromatin accessibility, and patterns of transcription factor (TF) binding activities. Collectively, these datasets facilitate a deeper understanding of the regulation tissue-resident stem cells use during aging and healing.

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Integration of Solid-State Nanopores in Microfluidic Networks via Transfer Printing of Suspended Membranes

et al. 2013

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Solid-state nanopores have emerged as versatile single-molecule sensors for applications including DNA sequencing, protein unfolding, micro-RNA detection, label-free detection of single nucleotide polymorphisms, and mapping of DNA-binding proteins involved in homologous recombination. While machining nanopores in dielectric membranes provides nanometer-scale precision, the rigid silicon support for the membrane contributes capacitive noise and limits integration with microfluidic networks for sample pre-processing. Herein, we demonstrate a technique to directly transfer solid-state nanopores machined in dielectric membranes from a silicon support into a microfluidic network. The resulting microfluidic-addressable nanopores can sense single DNA molecules at high bandwidths and with low noise, owing to significant reductions in membrane capacitance. This strategy will enable large-scale integration of solid-state nanopores with microfluidic upstream and downstream processing and permit new functions with nanopores such as complex manipulations for multidimensional analysis and parallel sensing in two and three-dimensional architectures.

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Micro- and nanoscale devices for the investigation of epigenetics and chromatin dynamics

Aguilar

Craighead

2013

Nature Nanotech

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DNA is the blueprint upon which life is based and transmitted, yet the manner in which chromatin, the dynamic complex of nucleic acids and proteins, is packaged and behaves within the cellular nucleus has only begun to be investigated. The packaging and modifications around the genome have been shown to exert significant influence on cellular behaviour and in turn, human development and disease. However, conventional techniques for studying epigenetic or conformational modifications of chromosomes have inherent limitations, and therefore, new methods based on micro- and nanoscale devices have been sought. Here, we review the development of these devices and explore their use in the study of DNA and chromatin modifications and higher order chromatin structure.

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Physical and Microscopic Characterization of Dry Whole Milk with Altered Lactose Content. 2. Effect of Lactose Crystallization

Aguilar

Ziegler

1994

Journal of Dairy Science

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Carlos A. Aguilar

Multiscale analysis of a regenerative therapy for treatment of volumetric muscle loss injury

Resolvin D1 supports skeletal myofiber regeneration via actions on myeloid and muscle stem cells

Unwavering Pathobiology of Volumetric Muscle Loss Injury

Direct micro-patterning of biodegradable polymers using ultraviolet and femtosecond lasers

Dissecting Murine Muscle Stem Cell Aging through Regeneration Using Integrative Genomic Analysis

Integration of Solid-State Nanopores in Microfluidic Networks via Transfer Printing of Suspended Membranes

Micro- and nanoscale devices for the investigation of epigenetics and chromatin dynamics

Physical and Microscopic Characterization of Dry Whole Milk with Altered Lactose Content. 2. Effect of Lactose Crystallization

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