• Journal of Chest Surgery
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• v.29 no.2
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• pp.199-207
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• 1996

Ischemic myocardial damage is inevitable to cardiac surgery. Myocardial damage after initiation of reperfusion through the coronary arteries is one of the most important determinants of a successful surgery. Adenosine is a potent vasodilator, and is also known to induce rapid cardioplegic arrest by its property of antagonizing cardiac calcium channels and activating the potassium channel. Thus, we initiated this study with adenosine to improve postischemic recovery in the isolated rat heart. We tested the hypothesis that adenosine could be more effective than potassium in inducing rapid cardiac arrest and enhancing postischemlc hemodynamic recovery. Isolated rat hearts, connected to the Langendorff appratus, were perfused with Krebs-Henseleit buffer and all hearts were subjected to arrest for 60 minutes. Three groups of hearts were studied according to the composition of cardioplegic solutions : Group A (n=10), adenosine 10mmo1/L+potassium free modified St. Thomas cardioplegia : Group B (n=10), adenosine 400mo1/L+S1. Thomas cardioplegia:Group C(control, n=10), St. Thomas cardioplegia. Adenosine-treated groups (group A & B) resulted in more rapid cardiac arrest than control group (C) (p< 0.01). There was greater improvement in recovery of coronary blood flow at 20 and 30 minutes of reperfusion in group A and at 20 minutes in group B when compared with control group(p<0.01). Recovery of systolic blood pressure at 10 minutes after reperfusion in group A and B was significantly superior to that in group C (p<0.01). Recovery of dp/dt at 10 minute after reperfusion in group A was also significantly superior to group C (p<0.05). Group A and B showed better recovery rates than control group in aortic blood flow, cardiac output, and heart rate, but there were no statistical differences. CPK levels of coronary flow in group A were significantly low (p< 0.01). We concluded that adenosine-enriched cardioplegic solutions have better effects on rapid cardiac arrest and postischemic recovery when compared with potassium cardioplegia.

• Korean Journal of Medicinal Crop Science
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• v.2 no.1
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• pp.86-94
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• 1994

This study was carried out to get information on the cause of low photosynthesis ofKorean ginseng, a shade plant. Photosynthesis, water content, stomatal conductance and water potential in leaves of ginseng and soybean were investigated. The light intensity for maximum photosynthesis was about $300{\mu}E\;/\;m^2\;/\;s^2$ in ginseng and about $800{\mu}E\;/\;m^2\;/\;s^2$ in soybean, respectively Photosynthesis was remarkably lower in ginseng than in soybean under the same light intensity and $temperature(at\;20^{\circ}C)$. Photosynthesis of detached leaves was stopped in shorter time in ginseng than in soybean particularly at high $temperature(30^{\circ}C)$. The decreasing rate of water content in detached leaves was slower in ginseng than that of soybean, while the remained water level in the leaves was much higher in $ginseng(70{\sim}71%)\;than\;in\;soybean(50{\sim}53%)$ when photosynthesis was stopped. Water content had a positive correlationwith photosynthesis in both plants. However, at the same water level, the ratio of photosynthesis to water content was remarkably lower in ginseng than In soybean. The relationship between the stomatal conductance and photosynthesis was significantly positive correlation in the both plants. The ratio of photosynthesis to stomatal conductance was similar in booth plants below about 40 $mmol\;/\;m^2\;/\;s\;at\;20^{\circ}C$. Water potential was remarkably lower in ginseng than in soybean, and waterpotential had a significantly positive correlation with water content, stomatal conductance and photosynthesis in both plant. These results suggested that the low stomatal conductance and low water potential might cause the low photosynthesis in ginseng compared to soybean.