• Journal of Pharmaceutical Investigation
• /
• v.19 no.4
• /
• pp.185-190
• /
• 1989

The release of angiotensin and ${\alpha}-amylase$ from monolithic devices of different molecular weight of polyethylene glycol (PEC) grafted polyurethane copolymer was investigated. Water-soluble PEG grafted polymer provided a controlled release of angiotensin and ${\alpha}-amylase$. The release rate of angiotensin and ${\alpha}-amylase$ could be controlled by varying the molecular weight of PEC grafted. The release mechanism may be associated with the creation of pore or domain through the devices following the gel swelling and self-aggregation by PEC grafted polymer. Hydrophobic polyurethane grafted with PEG can provide a biomaterial for prolonged release of angiotensin and ${\alpha}-amylase$ from angiotensin and ${\alpha}-amylase$ blended system.

• Journal of Pharmaceutical Investigation
• /
• v.18 no.4
• /
• pp.169-174
• /
• 1988

The release of heparin from monolithic devices composed of different ratios of polyethylene oxide-polypropylene oxide (PEO-PPO) and hydrophobic polyurethane was investigated. The release rate of heparin could be controlled by varying the PEO-PPO content. The heparin release rate from the devices increased as the content of PEO-PPO in the devices increased. The release mechanism may be associated with creation of micro-channels and pores through the devices following the change in the physical structure of the polymer network. Hydrophobic polyurethane containing PEO-PPO can provide an antithrombogenic material for prolonged release of heparin from a heparin blended system.

• Archives of Pharmacal Research
• /
• v.9 no.4
• /
• pp.193-199
• /
• 1986

The release of heparin from monolithic devices composed of different ratios of polythylene oxide (PEO MW 20,000) and hydrophobic polydimethylsiloxane or polyurethane was investigated. Water soluble PEO blended into the polymers provided a controlled release of heparin. The release rate of heparin could be controlled by varying the content of PEO. The heparin release rate from the devices increased as the content of PEO in the devices increased. The release mechanism may be associated with the creation of pore of domain through the devices following the swelling and the change in the physical structure of the polymer network. Hydrophobic polydimethylsiloxanes and polyurethanes containing PEO can provide an antith rombogenic material for prologed release of heparin from blended system.

• Macromolecular Research
• /
• v.8 no.4
• /
• pp.179-185
• /
• 2000

Generally vascular grafts with a relatively large inner diameter (> 5 mm) have been successfully employed for replacement in the human body. However, the use of small diameter grafts is limited, because these grafts rapidly occlude due to the thrombosis. The ideal blood-contacting surface of a prosthesis would be an endothelial cell (EC) lining, because the confluent monolayer of healthy ECs that culture natural blood vessels represents the ideal nonthrombogenic surface. For vascular graft application, the stable EC adhesion on surface under How conditions is very important. In this study, the adhesive strength of ECs attached on polymer surfaces coated with collagen type IV (Col IV), fibronectin (Fn), laminin (Ln), and treated with corona was investigated onto polyurethane (PU) films. The EC-attached PU surfaces were mounted on parallel-plate flow chambers in a How system prepared for cell adhesiveness test. Three different shear stresses (100, 150, and 200 dyne/㎠) were applied to the How chambers and each shear stress was maintained for 120 min to investigate the effect of shear stress and surface treatment condition on the EC adhesion strength. It was observed that the EC adhesion strength on the surface-modified PU films was in the order of Ln≡Fn > Col IV > corona 》 control. More than 70% of the adhered cells were remained on surface-modified PU surface after applying the shear stress,200 dyne/㎠ for 2 hrs, whereas the cells were completely detached on the control PU surface within 10 min after applying the same shear stress. It seems that the type of adsorbed proteins and hydrophilicitv onto the PU surfaces play very important roles for cell adhesion strength.