Doxycycline prevents blood-brain barrier dysfunction and microvascular hyperpermeability after traumatic brain injury.

The main objective of this study was to determine the cellular and molecular effects of doxycycline on the blood-brain barrier (BBB) and protection against secondary injuries following traumatic brain injury (TBI). Microvascular hyperpermeability and cerebral edema resulting from BBB dysfunction after TBI leads to elevation of intracranial pressure, secondary brain ischemia, herniation, and brain death. There are currently no effective therapies to modulate the underlying pathophysiology responsible for TBI-induced BBB dysfunction and hyperpermeability. The loss of BBB integrity by the proteolytic enzyme matrix metalloproteinase-9 (MMP-9) is critical to TBI-induced BBB hyperpermeability, and doxycycline possesses anti-MMP-9 effect. In this study, the effect of doxycycline on BBB hyperpermeability was studied utilizing molecular modeling (using Glide) in silico, cell culture-based models in vitro, and a mouse model of TBI in vivo. Brain microvascular endothelial cell assays of tight junction protein immunofluorescence and barrier permeability were performed. Adult C57BL/6 mice were subjected to sham versus TBI with or without doxycycline treatment and immediate intravital microscopic analysis for evaluating BBB integrity. Postmortem mouse brain tissue was collected to measure MMP-9 enzyme activity. It was found that doxycycline binding to the MMP-9 active sites have binding affinity of -7.07 kcal/mol. Doxycycline treated cell monolayers were protected from microvascular hyperpermeability and retained tight junction integrity (p < 0.05). Doxycycline treatment decreased BBB hyperpermeability following TBI in mice by 25% (p < 0.05). MMP-9 enzyme activity in brain tissue decreased with doxycycline treatment following TBI (p < 0.05). Doxycycline preserves BBB tight junction integrity following TBI via inhibiting MMP-9 activity. When established in human subjects, doxycycline, may provide readily accessible medical treatment after TBI to attenuate secondary injury.

Doxycycline improves traumatic brain injury outcomes in a murine survival model.

BACKGROUND: Traumatic brain injury (TBI) has significant morbidity and cost implications. Primary treatment modalities aim to decrease intracranial pressure; however, therapies targeting the underlying pathophysiology of a TBI are limited. The TBI-induced microvascular leak and secondary injury are largely due to proteolysis of the blood-brain barrier (BBB) by matrix metalloproteinase-9. We previously observed doxycycline's inhibitory affinity on matrix metalloproteinase-9 resulting in preserved BBB integrity in nonsurvival murine studies. This study sought to determine the effect of doxycycline on functional motor and behavioral outcomes in the setting of a TBI murine survival model. METHODS: C57BL/6J mice were assigned to a sham, TBI, or TBI with doxycycline arm. A moderate TBI was induced utilizing a controlled cortical impactor. The TBI with doxycycline cohort received a dose of doxycycline (20 mg/kg) 2 hours after injury and every 12 hours until postoperative day (POD) 6. All mice underwent preoperative testing for weight, modified neurological severity score, wire grip, and ataxia analysis (DigiGait). Postoperative testing was performed on POD 1, POD 3, and POD 6 for the same measures. SAS 9.4 was used for comparative analysis. RESULTS: Fifteen sham mice, 15 TBI mice, and 10 TBI with doxycycline mice were studied. Mice treated with doxycycline had significantly improved modified neurological severity score and wire grip scores at POD 1 (all p < 0.05). Mice treated with doxycycline had significantly improved ataxia scores by POD 3 and POD 6 (all p < 0.05). There was no significant difference in rate of weight change between the three groups. CONCLUSION: Mice treated with doxycycline following TBI demonstrated improved behavioral and motor function suggesting doxycycline's role in preserving murine BBB integrity. Examining the role of doxycycline in human TBIs is warranted given the relative universal accessibility, affordability, and safety profile of doxycycline.

Exploring blood-brain barrier hyperpermeability and potential biomarkers in traumatic brain injury.

Blood-brain barrier breakdown and associated vascular hyperpermeability leads to vasogenic edema in traumatic brain injury (TBI). Tight junctions maintain blood-brain barrier integrity; their disruption in TBI holds significant promise for diagnosis and treatment. A controlled cortical impactor was used for TBI in mouse studies. Blood was collected 1 h after injury and sent for antibody microarray analysis. Twenty human subjects with radiographic evidence of TBI were enrolled and blood collected within 48 h of admission. Control subjects were individuals with nontrauma diagnoses. The subjects were matched by age and gender. Enzyme-linked immunosorbent assays were performed on each TBI and control sample for tight junction-associated proteins (TJPs), inflammatory markers, and S100ß. Plasma was used to conduct in vitro monolayer permeability studies with human brain endothelial cells. S100ß and the TJP occludin were significantly elevated in TBI plasma in both the murine and human studies. Monolayer permeability studies showed increased hyperpermeability in TBI groups. Plasma from TBI subjects increases microvascular hyperpermeability in vitro. TJPs in the blood may be a potential biomarker for TBI.

Preoperative Frailty and Surgical Outcomes Across Diverse Surgical Subspecialties in a Large Health Care System.

BACKGROUND: Frailty is an emerging risk factor for surgical outcomes; however, its application across large populations is not well defined. We hypothesized that frailty affects postoperative outcomes in a large health care system. STUDY DESIGN: Frailty was prospectively measured in elective surgery patients (January 2016 to June 2017) in a health care system (4 hospitals/901 beds). Frailty classifications-low (0), intermediate (1 to 2), high (3 to 5)-were assigned based on the modified Hopkins score. Operations were classified as inpatient (IP) vs outpatient (OP). Outcomes measured (30-day) included major morbidity, discharge location, emergency department (ED) visit, readmission, length of stay (LOS), mortality, and direct-cost/patient. RESULTS: There were 14,530 elective surgery patients (68.1% outpatient, 31.9% inpatient) preoperatively assessed (cardiothoracic 4%, colorectal 4%, general 29%, oral maxillofacial 2%, otolaryngology 8%, plastic surgery 13%, podiatry 6%, surgical oncology 5%, transplant 3%, urology 24%, vascular 2%). High frailty was found in 3.4% of patients (5.3% IP, 2.5% OP). Incidence of major morbidity, readmission, and mortality correlated with frailty classification in all patients (p < 0.05). In the IP cohort, length of stay in days (low 1.6, intermediate 2.3, high 4.1, p < 0.0001) and discharge to facility increased with frailty (p < 0.05). In the OP cohort, ED visits increased with frailty (p < 0.05). Frailty was associated with increased direct-cost in the IP cohort (low, $7,045; intermediate, $7,995; high, $8,599; p < 0.05). CONCLUSIONS: Frailty affects morbidity, mortality, and health care resource use in both IP and OP operations. Additionally, IP cost increased with frailty. The broad applicability of frailty (across surgical specialties) represents an opportunity for risk stratification and patient optimization across a large health care system.

The Tri-phasic Role of Hydrogen Peroxide in Blood-Brain Barrier Endothelial cells.

Hydrogen peroxide (H2O2) plays an important role physiologically as the second messenger and pathologically as an inducer of oxidative stress in injury, ischemia and other conditions. However, it is unclear how H2O2 influences various cellular functions in health and disease differentially, particularly in the blood-brain barrier (BBB). We hypothesized that the change in cellular concentrations of H2O2 is a major contributor in regulation of angiogenesis, barrier integrity/permeability and cell death/apoptosis in BBB endothelial cells. Rat brain microvascular endothelial cells were exposed to various concentrations of H2O2 (1 nM to 25 mM). BBB tight junction protein (zonula ocludens-1; ZO-1) localization and expression, cytoskeletal organization, monolayer permeability, angiogenesis, cell viability and apoptosis were evaluated. H2O2 at low concentrations (0.001 µM to 1 µM) increased endothelial cell tube formation indicating enhanced angiogenesis. H2O2 at 100 µM and above induced monolayer hyperpermeability significantly (p < 0.05). H2O2 at 10 mM and above decreased cell viability and induced apoptosis (p < 0.05). There was a decrease of ZO-1 tight junction localization with 100 µm H2O2, but had no effect on protein expression. Cytoskeletal disorganizations were observed starting at 1 µm. In conclusion H2O2 influences angiogenesis, permeability, and cell death/apoptosis in a tri-phasic and concentration-dependent manner in microvascular endothelial cells of the blood-brain barrier.

Quetiapine protects the blood-brain barrier in traumatic brain injury.

BACKGROUND: The integrity of the blood-brain barrier (BBB) is paramount in limiting vasogenic edema following traumatic brain injury (TBI). The purpose of this study was to ascertain if quetiapine, an atypical antipsychotic commonly used in trauma/critical care for delirium, protects the BBB and attenuates hyperpermeability in TBI. METHODS: The effect of quetiapine on hyperpermeability was examined through molecular modeling, cellular models in vitro and small animal models in vivo. Molecular docking was performed with AutoDock Vina to matrix metalloproteinase-9. Rat brain microvascular endothelial cells (BMECs) were pretreated with quetiapine (20 µM; 1 hour) followed by an inflammatory activator (20 µg/mL chitosan; 2 hours) and compared to controls. Immunofluorescence localization for tight junction proteins zonula occludens-1 and adherens junction protein ß-catenin was performed. Human BMECs were grown as a monolayer and pretreated with quetiapine (20 µM; 1 hour) followed by chitosan (20 µg/mL; 2 hours), and transendothelial electrical resistance was measured. C57BL/6 mice (n = 5/group) underwent mild to moderate TBI (controlled cortical impactor) or sham craniotomy. The treatment group was given 10 mg/kg quetiapine intravenously 10 minutes after TBI. The difference in fluorescence intensity between intravascular and interstitium (ΔI) represented BBB hyperpermeability. A matrix metalloproteinase-9 activity assay was performed in brain tissue from animals in the experimental groups ex vivo. RESULTS: In silico studies showed quetiapine thermodynamically favorable binding to MMP-9. Junctional localization of zonula occludens-1 and ß-catenin showed retained integrity in quetiapine-treated cells as compared with the chitosan group in rat BMECs. Quetiapine attenuated monolayer permeability compared with chitosan group (p < 0.05) in human BMECs. In the animal studies, there was a significant decrease in BBB hyperpermeability and MMP-9 activity when compared between the TBI and TBI plus quetiapine groups (p < 0.05). CONCLUSION: Quetiapine treatment may have novel anti-inflammatory properties to provide protection to the BBB by preserving tight junction integrity. LEVEL OF EVIDENCE: level IV.

Measurement of Microvascular Endothelial Barrier Dysfunction and Hyperpermeability In Vitro.

Loss of microvascular endothelial barrier integrity leads to vascular hyperpermeability and vasogenic edema in a variety of disease processes including trauma, ischemia and sepsis. Understanding these principles gives valuable information on pathophysiology and therapeutic drug development. While animal models of traumatic and ischemic injuries are useful to understand vascular dysfunctions associated with such injuries, in vitro barrier integrity assays are reliable and helpful adjuncts to understand the cellular and molecular changes and signaling mechanisms that regulate barrier function. We describe here the endothelial monolayer permeability assay and transendothelial electrical resistance (TEER) measurement as in vitro methods to test changes in microvascular integrity and permeability. These in vitro assays are based on either the measurement of electrical resistance of the monolayer or the quantitative evaluation of fluorescently tagged molecules (e.g., FITC-dextran) that pass through the monolayer when there is damage or breakdown.

Attenuation of Blood-Brain Barrier Breakdown and Hyperpermeability by Calpain Inhibition.

Blood-brain barrier (BBB) breakdown and the associated microvascular hyperpermeability followed by brain edema are hallmark features of several brain pathologies, including traumatic brain injuries (TBI). Recent studies indicate that pro-inflammatory cytokine interleukin-1ß (IL-1ß) that is up-regulated following traumatic injuries also promotes BBB dysfunction and hyperpermeability, but the underlying mechanisms are not clearly known. The objective of this study was to determine the role of calpains in mediating BBB dysfunction and hyperpermeability and to test the effect of calpain inhibition on the BBB following traumatic insults to the brain. In these studies, rat brain microvascular endothelial cell monolayers exposed to calpain inhibitors (calpain inhibitor III and calpastatin) or transfected with calpain-1 siRNA demonstrated attenuation of IL-1ß-induced monolayer hyperpermeability. Calpain inhibition led to protection against IL-1ß-induced loss of zonula occludens-1 (ZO-1) at the tight junctions and alterations in F-actin cytoskeletal assembly. IL-1ß treatment had no effect on ZO-1 gene (tjp1) or protein expression. Calpain inhibition via calpain inhibitor III and calpastatin decreased IL-1ß-induced calpain activity significantly (p < 0.05). IL-1ß had no detectable effect on intracellular calcium mobilization or endothelial cell viability. Furthermore, calpain inhibition preserved BBB integrity/permeability in a mouse controlled cortical impact model of TBI when studied using Evans blue assay and intravital microscopy. These studies demonstrate that calpain-1 acts as a mediator of IL-1ß-induced loss of BBB integrity and permeability by altering tight junction integrity, promoting the displacement of ZO-1, and disorganization of cytoskeletal assembly. IL-1ß-mediated alterations in permeability are neither due to the changes in ZO-1 expression nor cell viability. Calpain inhibition has beneficial effects against TBI-induced BBB hyperpermeability.