概述
经典的家族性高胆固醇血症(familial hypercholesterolemia,FH)是一种常染色体(共)显性遗传病,其主要临床表现为血清低密度脂蛋白胆固醇(low density lipoprotein-cholesterol,LDL-C)水平明显升高,以及皮肤/腱黄色瘤[1]。FH是由于低密度脂蛋白受体(low density lipoprotein receptor,LDLR)介导的LDL在肝脏代谢有关的基因发生致病性突变所致,可分为杂合子(heterozygote familial hypercholesterolemia,HeFH)、纯合子(homozygote familial hypercholesterolemia,HoFH)、复合杂合子和双重杂合子4种类型,以前两类多见[2]。由于FH患者从出生就处于高血清LDL-C水平暴露状态,所以动脉粥样硬化性心血管疾病(arteriosclerotic cardiovascular disease,ASCVD)风险明显增高[3]。HoFH较为罕见,患病率为1/100万~3/100万,HoFH患者全身动脉粥样硬化发生早,进展快,可在儿童及青年期发生心绞痛或心肌梗死,并于20~30岁之前死亡;HeFH患病率约为0.20%~0.48%,未经治疗的HeFH患者早发冠心病风险亦显著高于正常人[4]。 临床特征 FH患者的发病呈家族聚集性,主要临床表现是血LDL-C水平明显增高和早发ASCVD,早期可无症状。 血清LDL-C水平明显升高:未治疗的HeFH患者血清LDL-C大多在5.0 mmol/L(191mg/dL)以上,HoFH患者血清LDL-C水平更高,常>13.0 mmol/L(500 mg/dL)[5]。 早发ASCVD:早发ASCVD是FH的主要临床表现之一,其中早发冠心病是常见的临床表型[6]。 黄色瘤:皮肤/腱黄色瘤是FH临床诊断的重要标志[7],多出现在肘关节、膝关节伸侧,或臀部及手部等部位,见图1。 脂性角膜弓:脂性角膜弓是角膜周边部基质内的类脂质沉积[8],见图2。 其他:HoFH患者可出现主动脉瓣叶和主动脉根部以及其他动脉钙化,部分患者还可出现主动脉瓣狭窄等[9]。 筛查与诊断 早期筛查和诊断是降低FH患者ASCVD发病风险、改善临床预后的重要举措,筛查和诊断流程如图3所示。 筛查流程和内容:[10]建议符合下列任意1项者要进入FH的筛查流程:(1) 早发ASCVD(男性<55岁或女性<65岁即发生ASCVD);(2) 成人血清LDL-C≥3.8mmol/L (146.7mg/dL)儿童血清LDL-C≥2.9 mmol/L (112.7mg/dL),且能除外继发性高脂血症者; (3) 有皮肤/腱黄色瘤或脂性角膜弓(<45岁); (4) 一级亲属中有上述3种情况。 诊断标准:作为遗传性疾病,基因检测到LDLR、Apo B、PCSK9和LDLRAP1基因致病性突变是诊断FH的金标准,但未发现上述基因突变并不能除外FH[11]。 鉴别诊断:在确诊FH前需要除外一些可能引起血LDL-C水平升高的疾病[12]。 继发性高胆固醇血症:甲状腺功能减退、肾病综合征等因素可出现继发性高胆固醇血症。 植物固醇血症( sitosterolemia / phytosterolaemia ):FH和植物固醇血症都以早发冠心病及全身黄色瘤为典型表现,植物固醇血症也是由基因突变所致, 但二者的致病基因不同。 治疗 治疗目标[13]:合并与不合并ASCVD的成人FH患者血LDL-C的目标值分别为<1.8 mmol/L(70 mg/dL)和<2.6 mmol/L(100 mg/dL);儿童FH患者血LDL-C的目标值<3.4 mmol/L(130 mg/dL)。若难以达到上述目标值,建议至少将血清LDL-C水平降低50%。治疗流程如图4所示。 治疗性生活方式改善[14]:健康科学的生活方式是FH治疗的基础措施,要鼓励患者戒烟,进食低饱和脂肪酸、低胆固醇饮食。控制体重,建议患者积极参加体育锻炼。建议FH患者在体育活动开始之前仔细评估心血管风险,特别是冠状动脉、主动脉和颅内动脉受累情况。 药物治疗[15]:FH诊断后应立即启动降胆固醇药物治疗。成人FH的治疗方案如下:(1) 他汀类药物:为首选药物,不仅可降低血LDL-C水平,还可改善FH患者的预后。建议使用最大耐受剂量的强效他汀。(2) 联合治疗:他汀类药物联合胆固醇吸收抑制剂依折麦布是联合治疗的首选推荐。(3) PCSK9抑制剂:能直接阻止循环中PCSK9与LDLR相结合,减少PCSK9介导的LDLR的分解,加强其对LDL-C的清除能力。 其他治疗[16]:包括:(1) 脂蛋白血浆置换:若药物联合治疗效果欠佳,可考虑血浆置换。(2) 肝脏移植和外科手术:通过肝移植纠正肝细胞上LDLR、PCSK9、Apo B等基因的的分子缺陷,但由于手术并发症和死亡率高/供体匮乏等因素不作为主要的治疗手段。(3) 基因治疗:该方法尚处于实验探索阶段。 参考文献: [1] Mabuchi H, Koizumi J, Shimizu M, et al. Develop ment of coronary heart disease in familial hypercholesterolemia. Circulation, 1989; 79: 225-232. [2] Nordestgaard BG, Chapman MJ, Humphries SE, et al. A: Familial hypercholesterolaemia is underdiagnosed and undertreated in the general population: guidance for clinicians to prevent cor onary heart disease: Consensus Statement of the European Atherosclerosis Society. Eur Heart J, 2013; 34: 3478-3490. [3] Ohta N, Hori M, Takahashi A, et al. Proprotein convertase subtilisin/kexin 9 V4I variant with LDLR mutations modifies the phenotype of familial hypercholesterolemia. J Clin Lipidol, 2015; 10: 547-555 e545. [4] Mabuchi H, Nohara A, Noguchi T, et al. Molecular genetic epidemiology of homozygous familial hypercholesterolemia in the Hokuriku district of Japan. Atherosclerosis, 2011; 214: 404-407. [5] Bujo H, Takahashi K, Saito Y, et al. 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