![Figure 4. RUC-1 protects hαIIb/mβ3 mice, but not WT mice from FeCl3-induced carotid artery thrombotic occlusion. Mice expressing the hybrid hαIIb/mβ3 receptor were injected intraperitoneally with vehicle control [1% (n = 2) or 10% DMSO (n = 6)], or RUC-1 (n = 8; 26.5 mg/kg) approximately 25 minutes before carotid artery injury. Carotid arteries were isolated by blunt dissection and treated with 20% FeCl3 for 3 minutes using a piece of filter paper. The surgical area was flushed with water, and blood flow through the carotid artery was monitored for 30 minutes with a Doppler flow probe. (A) Representative blood flow tracings from 2 mice treated with DMSO and 2 mice treated with RUC-1. Time to occlusion was calculated from the time the filter paper containing the FeCl3 was applied to the artery until the time when the arterial flow rate became undetectable. (B) Kaplan-Meier analysis of time to occlusion data in hαIIb/mβ3 mice receiving either RUC-1 (n = 8) or DMSO vehicle control (n = 8). (C) Kaplan-Meier analysis of time to occlusion data from RUC-1-treated mice comparing WT mice (n = 10) and hαIIb/mβ3 mice (n = 8, data repeated from panel B). (D,E) Hematoxylin and eosin stains of fixed cross-sections of carotid arteries in a mouse treated with DMSO as a control (left) and a mouse treated with RUC-1 (right). An extensive platelet thrombus nearly completely fills the lumen of the control animal's carotid artery, whereas there is minimal platelet thrombus formation in the carotid artery of RUC-1-treated animal. Most of the material in the lumen of the RUC-1-treated animal is trapped erythrocytes. The bar in panel D is 50 μm, and both panels D and E were photographed and reproduced at the same magnification.](https://ash.silverchair-cdn.com/ash/content_public/journal/blood/114/1/10.1182_blood-2008-08-169243/4/zh89990938330004.jpeg?Expires=1724254427&Signature=3nyFqmkvWZZkr7~qiUQJMVY4LRnm8pAzrUgt9fr4Y2awbTko9~6J-aCxoHmFSkmP1mSDue1QSNH8H9J5GFhFju-0u84W1A6vqs81OjKb2CQOoc2aWIWeSpNXFG5Hz4J4NaZp5RzLSjZ81mQtSzlKB0k92IF5fvjNFhS0r-oNjgqzislgOzlyfUaAWwLoytzRhoZzs8dScn9-S33Rb7VCYmvzSkE1YImBT~trblwtW-2l2G9dqjkr82Kp-hOlPx43ktNMjnR6roTcHNrv4zys4fTt8Oz2HZ1j4aK4wj4h9NyOc~41j8~RDGXxtqTBjgWdcyvYai84wTJ5ZxTRcRDCbw__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
RUC-1 protects hαIIb/mβ3 mice, but not WT mice from FeCl3-induced carotid artery thrombotic occlusion. Mice expressing the hybrid hαIIb/mβ3 receptor were injected intraperitoneally with vehicle control [1% (n = 2) or 10% DMSO (n = 6)], or RUC-1 (n = 8; 26.5 mg/kg) approximately 25 minutes before carotid artery injury. Carotid arteries were isolated by blunt dissection and treated with 20% FeCl3 for 3 minutes using a piece of filter paper. The surgical area was flushed with water, and blood flow through the carotid artery was monitored for 30 minutes with a Doppler flow probe. (A) Representative blood flow tracings from 2 mice treated with DMSO and 2 mice treated with RUC-1. Time to occlusion was calculated from the time the filter paper containing the FeCl3 was applied to the artery until the time when the arterial flow rate became undetectable. (B) Kaplan-Meier analysis of time to occlusion data in hαIIb/mβ3 mice receiving either RUC-1 (n = 8) or DMSO vehicle control (n = 8). (C) Kaplan-Meier analysis of time to occlusion data from RUC-1-treated mice comparing WT mice (n = 10) and hαIIb/mβ3 mice (n = 8, data repeated from panel B). (D,E) Hematoxylin and eosin stains of fixed cross-sections of carotid arteries in a mouse treated with DMSO as a control (left) and a mouse treated with RUC-1 (right). An extensive platelet thrombus nearly completely fills the lumen of the control animal's carotid artery, whereas there is minimal platelet thrombus formation in the carotid artery of RUC-1-treated animal. Most of the material in the lumen of the RUC-1-treated animal is trapped erythrocytes. The bar in panel D is 50 μm, and both panels D and E were photographed and reproduced at the same magnification.
