化工进展
化工進展
화공진전
CHEMICAL INDUSTRY AND ENGINEERING PROGRESS
2014年
7期
1850-1855,1870
,共7页
组织工程支架%微管流场%数值模拟
組織工程支架%微管流場%數值模擬
조직공정지가%미관류장%수치모의
tissue engineering%scaffolds%flow field of microtubule%numerical simulation
骨支架内部微管结构对营养液和细胞在其内部的流动有着非常重要的影响。利用流体计算软件 Fluent 对不同尺寸的人工骨微管结构内部营养液和细胞的流动状况进行了数值模拟,得到了不同几何结构骨支架内部流场的速度和压力分布图。结果表明,从进口到出口,主管道内流体流速随管道的深入不断减小。上端浮克曼管中流体流速比下端浮克曼管中流体流速高,但是比同一高度主管道内流体流速低。哈佛氏管与第一行浮克曼管交叉处下端的哈佛氏管内存在流动缓慢区,第三行浮克曼管与哈佛氏管交叉处开始,流体速度不断增大。随浮克曼管长度的增加,上端哈佛氏管中流体流动的缓慢区减小;随浮克曼管直径的增加,浮克曼管中的流速有所增加,并且各微管中流体的流速更为均匀;随浮克曼管与主管道夹角的增加,骨支架各微管内流体流速更加均匀,利于细胞和营养液在各管道的输运。本数值模拟范围内,最佳骨支架结构参数为浮克曼管长度3mm,直径0.6mm,浮克曼管与主管道夹角90°。
骨支架內部微管結構對營養液和細胞在其內部的流動有著非常重要的影響。利用流體計算軟件 Fluent 對不同呎吋的人工骨微管結構內部營養液和細胞的流動狀況進行瞭數值模擬,得到瞭不同幾何結構骨支架內部流場的速度和壓力分佈圖。結果錶明,從進口到齣口,主管道內流體流速隨管道的深入不斷減小。上耑浮剋曼管中流體流速比下耑浮剋曼管中流體流速高,但是比同一高度主管道內流體流速低。哈彿氏管與第一行浮剋曼管交扠處下耑的哈彿氏管內存在流動緩慢區,第三行浮剋曼管與哈彿氏管交扠處開始,流體速度不斷增大。隨浮剋曼管長度的增加,上耑哈彿氏管中流體流動的緩慢區減小;隨浮剋曼管直徑的增加,浮剋曼管中的流速有所增加,併且各微管中流體的流速更為均勻;隨浮剋曼管與主管道夾角的增加,骨支架各微管內流體流速更加均勻,利于細胞和營養液在各管道的輸運。本數值模擬範圍內,最佳骨支架結構參數為浮剋曼管長度3mm,直徑0.6mm,浮剋曼管與主管道夾角90°。
골지가내부미관결구대영양액화세포재기내부적류동유착비상중요적영향。이용류체계산연건 Fluent 대불동척촌적인공골미관결구내부영양액화세포적류동상황진행료수치모의,득도료불동궤하결구골지가내부류장적속도화압력분포도。결과표명,종진구도출구,주관도내류체류속수관도적심입불단감소。상단부극만관중류체류속비하단부극만관중류체류속고,단시비동일고도주관도내류체류속저。합불씨관여제일행부극만관교차처하단적합불씨관내존재류동완만구,제삼행부극만관여합불씨관교차처개시,류체속도불단증대。수부극만관장도적증가,상단합불씨관중류체류동적완만구감소;수부극만관직경적증가,부극만관중적류속유소증가,병차각미관중류체적류속경위균균;수부극만관여주관도협각적증가,골지가각미관내류체류속경가균균,리우세포화영양액재각관도적수운。본수치모의범위내,최가골지가결구삼수위부극만관장도3mm,직경0.6mm,부극만관여주관도협각90°。
The microtubule structure of the bone scaffold has a considerable influence on the flow of nutrient solution and cells. The flow status of nutrient solution and cells in microtubules with different sizes was numerically simulated by using software Fluent. Velocity distribution and pressure distribution in the microtubule structure of the bone scaffold were obtained. The fluid velocity of the main pipe decreased with increasing pipe depth from inlet to outlet. The fluid velocity of the upper end of Volkmann tubes was faster than that of the lower end,but slower than that of the main pipe at the same height. A slow flowing area was observed in the intersection of the Harvard’s tube and the first line Volkmann tube. The velocity of Harvard’s tube increased from the intersection of the third line Volkmann tube and Harvard’s tube. The flowing slow area at the top of the Harvard’s tubes decreased as the length of Volkmann tubes increased. The velocity of Volkmann tubes was increasing and the flowing velocity of each tube was more uniform with the increase of the diameter of the Volkmann tubes. With increasing angle between Volkmann tubes and main pipe,the flow velocity of each scaffold tube was more uniform which was favorable for the transport of cells and nutrient solution in the pipe. In the range of this paper,the optimal parameters of bone scaffold structure were obtained as follows:Volkmann length of 3mm,diameter of 0.6mm and the angle between Volkmann tubes and the main pipe of 90°.