Magnetic Nanoparticle-Mediated Targeting of Cell Therapy Reduces In-Stent Stenosis in Injured Arteries.

Although drug-eluting stents have dramatically reduced the recurrence of restenosis after vascular interventions, the nonselective antiproliferative drugs released from these devices significantly delay reendothelialization and vascular healing, increasing the risk of short- and long-term stent failure. Efficient repopulation of endothelial cells in the vessel wall following injury may limit complications, such as thrombosis, neoatherosclerosis, and restenosis, through reconstitution of a luminal barrier and cellular secretion of paracrine factors. We assessed the potential of magnetically mediated delivery of endothelial cells (ECs) to inhibit in-stent stenosis induced by mechanical injury in a rat carotid artery stent angioplasty model. ECs loaded with biodegradable superparamagnetic nanoparticles (MNPs) were administered at the distal end of the stented artery and localized to the stent using a brief exposure to a uniform magnetic field. After two months, magnetic localization of ECs demonstrated significant protection from stenosis at the distal part of the stent in the cell therapy group compared to both the proximal part of stent in the cell therapy group and the control (stented, nontreated) group: 1.7-fold (p < 0.001) less reduction in lumen diameter as measured by B-mode and color Doppler ultrasound, 2.3-fold (p < 0.001) less reduction in the ratios of peak systolic velocities as measured by pulsed wave Doppler ultrasound, and 2.1-fold (p < 0.001) attenuation of stenosis as determined through end point morphometric analysis. The study thus demonstrates that magnetically assisted delivery of ECs is a promising strategy for prevention of vessel lumen narrowing after stent angioplasty procedure.

Porcine intact and wounded skin responses to atmospheric nonthermal plasma.

Thermal plasma is a valued tool in surgery for its coagulative and ablative properties. We suggested through in vitro studies that nonthermal plasma can sterilize tissues, inactive pathogens, promote coagulation, and potentiate wound healing. The present research was undertaken to study acute toxicity in porcine skin tissues. We demonstrate that floating electrode-discharge barrier discharge (FE-DBD) nonthermal plasma is electrically safe to apply to living organisms for short periods. We investigated the effects of FE-DBD plasma on Yorkshire pigs on intact and wounded skin immediately after treatment or 24h posttreatment. Macroscopic or microscopic histological changes were identified using histological and immunohistochemical techniques. The changes were classified into four groups for intact skin: normal features, minimal changes or congestive changes, epidermal layer damage, and full burn and into three groups for wounded skin: normal, clot or scab, and full burn-like features. Immunohistochemical staining for laminin layer integrity showed compromise over time. A marker for double-stranded DNA breaks, γ-H2AX, increased over plasma-exposure time. These findings identified a threshold for plasma exposure of up to 900s at low power and <120s at high power. Nonthermal FE-DBD plasma can be considered safe for future studies of external use under these threshold conditions for evaluation of sterilization, coagulation, and wound healing.

Assessing breast cancer margins ex vivo using aqueous quantum-dot-molecular probes.

Positive margins have been a critical issue that hinders the success of breast- conserving surgery. The incidence of positive margins is estimated to range from 20% to as high as 60%. Currently, there is no effective intraoperative method for margin assessment. It would be desirable if there is a rapid and reliable breast cancer margin assessment tool in the operating room so that further surgery can be continued if necessary to reduce re-excision rate. In this study, we seek to develop a sensitive and specific molecular probe to help surgeons assess if the surgical margin is clean. The molecular probe consists of the unique aqueous quantum dots developed in our laboratory conjugated with antibodies specific to breast cancer markers such as Tn-antigen. Excised tumors from tumor-bearing nude mice were used to demonstrate the method. AQD-Tn mAb probe proved to be sensitive and specific to identify cancer area quantitatively without being affected by the heterogeneity of the tissue. The integrity of the surgical specimen was not affected by the AQD treatment. Furthermore, AQD-Tn mAb method could determine margin status within 30 minutes of tumor excision, indicating its potential as an accurate intraoperative margin assessment method.

Carbon monoxide-releasing molecule-2 decreases fibrinolysis in vitro and in vivo in the rabbit.

Administration of carbon monoxide derived from carbon monoxide-releasing molecules (CORMs) have been demonstrated to enhance coagulation and diminish fibrinolysis in vitro at small concentrations (100-200 µmol/l) in human and rabbit plasma, whereas in vivo administration of large concentrations (>1400 µmol/l) of carbon monoxide has mildly increased bleeding time in vivo in rats. We sought to determine whether CORM-2 [tricarbonyldichlororuthenium (II) dimer] would improve coagulation and attenuate tissue-type plasminogen activator (tPA)-mediated fibrinolysis in rabbit whole blood as determined in vitro by thrombelastography and in an in vivo preclinical rabbit model of ear bleeding time administered intravenous tPA (1 mg/kg). Addition of 200, 400 and 600 µmol/l CORM-2 to whole blood significantly improved coagulation and attenuated fibrinolysis compared with blood without CORM-2. Rabbits administered CORM-2 (10 mg/kg, 279 µmol/l) had a small but significant decrease in bleeding time before tPA administration. Administration of tPA resulted in bleeding times more than six-fold greater than baseline in animals not exposed to CORM-2, whereas rabbits administered CORM-2 had significantly smaller (more than five-fold less) bleeding time values after tPA administration. CORM-2 administration significantly decreases fibrinolytic bleeding in the rabbit in vivo. Additional preclinical investigation of the effects of CORM-2 on coagulopathy (e.g. heparin-mediated or clopidogrel-mediated) utilizing this rabbit model are planned.

Carbon monoxide-releasing molecule-2 enhances coagulation in rabbit plasma and decreases bleeding time in clopidogrel/aspirin-treated rabbits.

Administration of carbon monoxide derived from carbon monoxide-releasing molecules has been demonstrated to enhance coagulation in vitro at small concentrations (100-200 µmol/l) in human and rabbit plasma. We sought to determine if carbon monoxide-releasing molecule-2 [tricarbonyldichlororuthenium (II) dimer, CORM-2] would improve coagulation in rabbit plasma in vitro via thrombelastography and in an in vivo preclinical rabbit model of ear bleeding time following administration of clopidogrel (20 mg/kg) with aspirin (10 mg/kg) via gavage. Addition of 100 µmol/l CORM-2 to rabbit plasma significantly improved coagulation. This procoagulant effect was blocked by pre-exposure of plasma to an agent that converts hemefibrinogen to methemefibrinogen in human plasma, preventing carbon monoxide binding and enhancement of coagulation. Rabbit ear bleeding time was 5.8 ±â€Š1.1 min 2-3 h after clopidogrel/aspirin administration. Bleeding time significantly decreased to 2.6 ±â€Š0.6 min, 5 min after administration of CORM-2 (10 mg/kg; 279 µmol/l 'best-case' instantaneous concentration) intravenously. CORM-2 enhances plasmatic coagulation in a manner similar to that of human plasma in vitro, and plasmatic coagulation is enhanced in vivo by CORM-2 as well. Additional preclinical investigation of the effects of CORM-2 on coagulopathy (e.g. heparin or hemodilution mediated) utilizing this rabbit model is planned.