组合型人工肝的研究进展
DOI: 10.12449/JCH240203
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摘要: 目前体外人工肝支持系统在各种原因导致的肝衰竭、肝移植前后无功能时期、严重胆汁性淤积等疾病中取得良好治疗效果。其中非生物型人工肝(NBAL)通过各种模式互补组合广泛应用于临床,主要以改善机体凝血因子和白蛋白等物质的血浆置换模式联合其余增强清除体内有毒物质谱的模式。以肝细胞的合成、转化功能为设计理念的生物型人工肝(BAL)近年也取得飞速发展。肝衰竭患者先经NBAL解毒后,再予以BAL合成、转化体内活性物质,能更接近人体肝脏正常生理功能。根据患者病情个体化组合NBAL模式,再结合疗效稳定的BAL是未来重症肝病患者体外支持治疗方向。Abstract: At present, in vitro artificial liver support system has achieved a good therapeutic effect in the diseases such as liver failure due to various causes, non-function state before and after liver transplantation, and severe cholestasis. Non-bioartificial liver (NBAL) is widely used in clinical practice through various combinations of modes, mainly the plasma exchange mode for improving coagulation factors and albumin combined with other modes for enhancing the elimination of toxic substances in the body. Bioartificial liver (BAL), based on the design concept of the synthesis and transformation of hepatocytes, has achieved rapid development in recent years. Patients with liver failure can almost obtain the normal physiological function of human liver after NBAL detoxification and BAL synthesis and transformation of active substances in the body. NBAL mode combined with BAL with a stable therapeutic effect according to the conditions of the patient is the direction of in vitro support treatment for patients with severe liver disease in the future.
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表 1 组合型NBAL模型的优缺点[2]
Table 1. Advantages and disadvantages of combined NBAL model
国内常见的NBAL组合模式 优点 缺点 DPMAS+PE 特异性高效吸附胆红素、清除毒素,补充凝血因子及白蛋白 无法改善肾功能,以血浆为置换液行PE时可能会加重肝性脑病 PE+HDF 毒素清除范围与程度增加,改善肾功能不全与肝性脑病,维持内环境稳定 血浆需求量较大,治疗时间相对较长 HDF+DPMAS 不需要用血浆,对胆红素、炎性介质、内毒素、中小分子水溶性毒素清除能力强 无法补充白蛋白、凝血因子等,治疗时间长 PDF+PP 减少血浆应用量,更有效地清除胆红素及其他大分子毒素,补充凝血因子及白蛋白 治疗时间长,重症患者的凝血监测与抗凝要求高 PE+PP+HDF 对大、中、小分子毒素都具有很好的清除能力,同时补充凝血因子 血浆需求量较大,治疗时间长,需给予合理的抗凝方案及监测 注:DPMAS,双重血浆分子吸附系统。 表 2 国内外常见的BAL来源与研究进展
Table 2. Sources and research progress of common BAL
系统 细胞来源 反应器 来源 相关研究结果 国内 hiHep-BAL 转分化细胞hiHep 多层平板模型 (1) NCT05035108; (2) NCT03084198; (3)微知卓生物科技有限公司 动物肝切除模型和临床扩大肝切除患者研究中,改善肝功能,增加术后肝脏再生速度,提高存活率[35-36] RL1-BAL 未知 未知 NCT04195282 比较PE与RL1-BAL+PE治疗HBV-ACLF的效果与预后。目前尚无相关临床指标。具体详细情况未公布 HepAssis2-BAL 人源肝细胞HL2 中空纤维反应器 (1) ChiCTR2300075781; (2) 武汉仝干医疗科技股份有限公司 相比NBAL组,BAL组的血浆用量显著减少,生化指标降低幅度两组相当,长期无肝移植存活率显著升高。 (结果来源该公司官网 http://www.whtogo.com/detail_254.html) IHH-BAL 永生化细胞IHH 微囊悬液式 苏州瑞徕生物科技有限公司 临床试验进行中,未见相关结果展示 ZHJ-Ⅲ系统 永生化细胞HepGL 灌流式 (1) ChiCTR1800016021; (2)广州乾晖生物科技有限公司 临床前研究阶段,结果尚未公布 Aliver系统 转分化细胞HepLPC 气液交互式 上海赛立维生物科技有限公司 临床前研究阶段。Ali-Cell肝细胞的BAL可以对肝衰竭患者血浆进行代谢解毒,并合成活性物质减轻肝损伤促进肝脏再生修复[37] 国外 LifeLiver系统 未知 未知 (1) NCT03882346; (2)韩国三星医疗HLB Cell Co.公司 目前注册的研究是关于在等待紧急肝移植的急性或ACLF患者中的安全性和有效性,未见相关结果展示 ELAD系统 人肝癌细胞株C3A细胞 中空纤维反应器 (1) NCT01875874; (2) NCT01829347; (3) Vital therapies公司 Ⅲ期临床试验中因初期疗效不佳,ELAD相关研究已提前终止,无明确结果[38] HepatAssist系统 猪源肝细胞 中空纤维反应器 Circe biomedical公司 该系统已进行相关临床研究,尽管研究证明没有猪逆转录病毒感染的安全性问题,但是临床疗效仍然存在争议,处于Ⅲ期临床阶段[33] BLSS系统 猪源肝细胞 中空纤维反应器 (1) Excorp Medical公司; (2)匹兹堡大学; (3) PubMed 与HepatAssist的区别是没有活性炭,目前在Ⅰ~Ⅱ期临床阶段[42] MELS系统 原代人肝细胞/猪源肝细胞 中空纤维反应器 (1)柏林堡大学; (2) PubMed 基于3D构建的人肝细胞反应器,进入Ⅱ期临床阶段,也有采用猪肝细胞反应器,初步研究排除猪逆转录病毒感染风险[43] -
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