Your browser doesn't support javascript.
loading
Show: 20 | 50 | 100
Results 1 - 6 de 6
Filter
Add more filters

Database
Language
Publication year range
1.
Adv Funct Mater ; 33(28)2023 Jul 11.
Article in English | MEDLINE | ID: mdl-37873031

ABSTRACT

Current screening and diagnostic tools for traumatic brain injury (TBI) have limitations in sensitivity and prognostication. Aberrant protease activity is a central process that drives disease progression in TBI and is associated with worsened prognosis; thus direct measurements of protease activity could provide more diagnostic information. In this study, a nanosensor is engineered to release a measurable signal into the blood and urine in response to activity from the TBI-associated protease calpain. Readouts from the nanosensor were designed to be compatible with ELISA and lateral flow assays, clinically-relevant assay modalities. In a mouse model of TBI, the nanosensor sensitivity is enhanced when ligands that target hyaluronic acid are added. In evaluation of mice with mild or severe injuries, the nanosensor identifies mild TBI with a higher sensitivity than the biomarker GFAP. This nanosensor technology allows for measurement of TBI-associated proteases without the need to directly access brain tissue, and has the potential to complement existing TBI diagnostic tools.

2.
Mol Pharm ; 18(2): 522-538, 2021 02 01.
Article in English | MEDLINE | ID: mdl-32584042

ABSTRACT

Acute brain injuries such as traumatic brain injury and stroke affect 85 million people a year worldwide, and many survivors suffer from long-term physical, cognitive, or psychosocial impairments. There are few FDA-approved therapies that are effective at preventing, halting, or ameliorating the state of disease in the brain after acute brain injury. To address this unmet need, one potential strategy is to leverage the unique physical and biological properties of nanomaterials. Decades of cancer nanomedicine research can serve as a blueprint for innovation in brain injury nanomedicines, both to emulate the successes and also to avoid potential pitfalls. In this review, we discuss how shared disease physiology between cancer and acute brain injuries can inform the design of novel nanomedicines for acute brain injuries. These disease hallmarks include dysregulated vasculature, an altered microenvironment, and changes in the immune system. We discuss several nanomaterial strategies that can be engineered to exploit these disease hallmarks, for example, passive accumulation, active targeting of disease-associated signals, bioresponsive designs that are "smart", and immune interactions.


Subject(s)
Brain Injuries, Traumatic/drug therapy , Drug Carriers/chemistry , Nanoparticles/chemistry , Neuroprotective Agents/administration & dosage , Stroke/drug therapy , Animals , Biological Availability , Blood-Brain Barrier/metabolism , Brain/immunology , Brain/pathology , Brain Injuries, Traumatic/pathology , Disease Models, Animal , Humans , Neoplasms/drug therapy , Neoplasms/immunology , Neoplasms/pathology , Neuroprotective Agents/pharmacokinetics , Permeability , Stroke/pathology , Tissue Distribution , Tumor Microenvironment/drug effects , Tumor Microenvironment/immunology
3.
Adv Mater ; 36(31): e2301738, 2024 Aug.
Article in English | MEDLINE | ID: mdl-38780012

ABSTRACT

Traumatic brain injury (TBI) is a critical public health concern, yet there are no therapeutics available to improve long-term outcomes. Drug delivery to TBI remains a challenge due to the blood-brain barrier and increased intracranial pressure. In this work, a chemical targeting approach to improve delivery of materials to the injured brain, is developed. It is hypothesized that the provisional fibrin matrix can be harnessed as an injury-specific scaffold that can be targeted by materials via click chemistry. To accomplish this, the brain clot is engineered in situ by delivering fibrinogen modified with strained cyclooctyne (SCO) moieties, which incorporated into the injury lesion and is retained there for days. Improved intra-injury capture and retention of diverse, clickable azide-materials including a small molecule azide-dye, 40 kDa azide-PEG nanomaterial, and a therapeutic azide-protein in multiple dosing regimens is subsequently observed. To demonstrate therapeutic translation of this approach, a reduction in reactive oxygen species levels in the injured brain after delivery of the antioxidant catalase, is achieved. Further, colocalization between azide and SCO-fibrinogen is specific to the brain over off-target organs. Taken together, a chemical targeting strategy leveraging endogenous clot formation is established which can be applied to improve therapeutic delivery after TBI.


Subject(s)
Azides , Brain Injuries, Traumatic , Fibrinogen , Brain Injuries, Traumatic/drug therapy , Brain Injuries, Traumatic/metabolism , Brain Injuries, Traumatic/pathology , Animals , Azides/chemistry , Fibrinogen/metabolism , Fibrinogen/chemistry , Click Chemistry , Fibrin/metabolism , Fibrin/chemistry , Reactive Oxygen Species/metabolism , Brain/metabolism , Brain/drug effects , Brain/pathology , Mice , Catalase/metabolism , Polyethylene Glycols/chemistry , Rats , Cyclooctanes/chemistry , Drug Delivery Systems , Blood-Brain Barrier/metabolism , Blood-Brain Barrier/drug effects
4.
ACS Biomater Sci Eng ; 10(7): 4279-4296, 2024 Jul 08.
Article in English | MEDLINE | ID: mdl-38870483

ABSTRACT

After traumatic brain injury, the brain extracellular matrix undergoes structural rearrangement due to changes in matrix composition, activation of proteases, and deposition of chondroitin sulfate proteoglycans by reactive astrocytes to produce the glial scar. These changes lead to a softening of the tissue, where the stiffness of the contusion "core" and peripheral "pericontusional" regions becomes softer than that of healthy tissue. Pioneering mechanotransduction studies have shown that soft substrates upregulate intermediate filament proteins in reactive astrocytes; however, many other aspects of astrocyte biology remain unclear. Here, we developed a platform for the culture of cortical astrocytes using polyacrylamide (PA) gels of varying stiffness (measured in Pascal; Pa) to mimic injury-related regions in order to investigate the effects of tissue stiffness on astrocyte reactivity and morphology. Our results show that substrate stiffness influences astrocyte phenotype; soft 300 Pa substrates led to increased GFAP immunoreactivity, proliferation, and complexity of processes. Intermediate 800 Pa substrates increased Aggrecan+, Brevican+, and Neurocan+ astrocytes. The stiffest 1 kPa substrates led to astrocytes with basal morphologies, similar to a physiological state. These results advance our understanding of astrocyte mechanotransduction processes and provide evidence of how substrates with engineered stiffness can mimic the injury microenvironment.


Subject(s)
Acrylic Resins , Astrocytes , Mechanotransduction, Cellular , Astrocytes/metabolism , Animals , Acrylic Resins/chemistry , Cells, Cultured , Glial Fibrillary Acidic Protein/metabolism , Rats , Gels/chemistry , Cell Proliferation , Rats, Sprague-Dawley
5.
Adv Healthc Mater ; 12(25): e2300782, 2023 Oct.
Article in English | MEDLINE | ID: mdl-37390094

ABSTRACT

Traumatic brain injury (TBI) affects millions of people each year and, in many cases, results in long-term disabilities. Once a TBI has occurred, there is a significant breakdown of the blood-brain barrier resulting in increased vascular permeability and progression of the injury. In this study, the use of an infusible extracellular matrix-derived biomaterial (iECM) for its ability to reduce vascular permeability and modulate gene expression in the injured brain is investigated. First, the pharmacokinetics of iECM administration in a mouse model of TBI is characterized, and the robust accumulation of iECM at the site of injury is demonstrated. Next, it is shown that iECM administration after injury can reduce the extravasation of molecules into the brain, and in vitro, iECM increases trans-endothelial electrical resistance across a monolayer of TNFα-stimulated endothelial cells. In gene expression analysis of brain tissue, iECM induces changes that are indicative of downregulation of the proinflammatory response 1-day post-injury/treatment and neuroprotection at 5 days post-injury/treatment. Therefore, iECM shows potential as a treatment for TBI.


Subject(s)
Brain Injuries, Traumatic , Brain Injuries , Humans , Mice , Animals , Endothelial Cells , Brain Injuries/drug therapy , Brain Injuries/metabolism , Brain/metabolism , Blood-Brain Barrier/metabolism , Disease Models, Animal
6.
ACS Nano ; 15(12): 20504-20516, 2021 12 28.
Article in English | MEDLINE | ID: mdl-34870408

ABSTRACT

Traumatic brain injury (TBI) is a critical public health concern and major contributor to death and long-term disability. After the initial trauma, a sustained secondary injury involving a complex continuum of pathophysiology unfolds, ultimately leading to the destruction of nervous tissue. One disease hallmark of TBI is ectopic protease activity, which can mediate cell death, extracellular matrix breakdown, and inflammation. We previously engineered a fluorogenic activity-based nanosensor for TBI (TBI-ABN) that passively accumulates in the injured brain across the disrupted vasculature and generates fluorescent signal in response to calpain-1 cleavage, thus enabling in situ visualization of TBI-associated calpain-1 protease activity. In this work, we hypothesized that actively targeting the extracellular matrix (ECM) of the injured brain would improve nanosensor accumulation in the injured brain beyond passive delivery alone and lead to increased nanosensor activation. We evaluated several peptides that bind exposed/enriched ECM constituents in the brain and discovered that nanomaterials modified with peptides that target hyaluronic acid (HA) displayed widespread distribution across the injury lesion, in particular colocalizing with perilesional and hippocampal neurons. Modifying TBI-ABN with HA-targeting peptide led to increases in activation in a ligand-valency-dependent manner, up to 6.6-fold in the injured cortex compared to a nontargeted nanosensor. This robust nanosensor activation enabled 3D visualization of injury-specific protease activity in a cleared and intact brain. In our work, we establish that targeting brain ECM with peptide ligands can be leveraged to improve the distribution and function of a bioresponsive imaging nanomaterial.


Subject(s)
Brain Injuries, Traumatic , Brain Injuries , Brain/metabolism , Calpain/metabolism , Extracellular Matrix/metabolism , Humans
SELECTION OF CITATIONS
SEARCH DETAIL