1 World Health Organization.Deafness and hearing loss.Geneva:World Health Organization,2020.Accessed 2020 December 25.Available from:https://www.who.int/news-room/fact-sheets/detail/deafness-and-hearing-loss.

2 Carpena NT,Lee MY.Genetic hearing loss and gene therapy[J].Genomics Inform,2018,16(4):e20.

3 Miller KA,Williams LH,Rose E,et al.Inner ear morphology is perturbed in two novel mouse models of recessive deafness[J].PLoS One,2012,7(12):e51284.

4 Hosoya M,Fujioka M,Sone T,et al.Cochlear cell modeling using disease-specific iPSCs unveils a degenerative phenotype and suggests treatments for congenital progressive hearing loss[J].Cell Rep,2017,18(1):68-81.

5 Alesutan I,Daryadel A,Mohebbi N,et al.Impact of bicarbonate,ammonium chloride,and acetazolamide on hepatic and renal SLC26A4 expression[J].Cell Physiol Biochem,2011,28(3):553-558.

6 Kopp P,Bizhanova A,Pesce L.The controversial role of pendrin in thyroid cell function and in the thyroid phenotype in Pendred syndrome[M].The Role of Pendrin in Health and Disease.America:Springer,Cham.2017.107-118.

7 Dossena S,Nofziger C,Tamma G,et al.Molecular and functional characterization of human pendrin and its allelic variants[J].Cell Physiol Biochem,2011,28(3):451-466.

8 Rose J,Muskett JA,King KA,et al.Hearing loss associated with enlarged vestibular aqueduct and zero or one mutant allele of SLC26A4[J].Laryngoscope,2017,127(7):E238-E243.

9 朱美婵，周枫，王蒙，等.广东省59例大前庭水管综合征患者SLC26A4基因突变及表型分析[J].听力学及言语疾病杂志，2016,24(4):335-339.

10 Bizhanova A,Kopp P.Genetics and phenomics of Pendred syndrome[J].Mol Cell Endocrinol,2010,322(1-2):83-90.

11 Rose J,Muskett JA,King KA,et al.Hearing loss associated with enlarged vestibular aqueduct and zero or one mutant allele of SLC26A4[J].Laryngoscope,2017,127(7):E238-E243.

12 El-Badry MM,Osman NM,Mohamed HM,et al.Evaluation of the radiological criteria to diagnose large vestibular aqueduct syndrome[J].Int J Pediatr Otorhinolaryngol,2016,81:84-91.

13 张宇丽，刘军.大前庭水管综合征的临床表现、诊断及防治策略[J].听力学及言语疾病杂志，2014,22(4):436-439.

14 赵晓云，胡健，仵倩，等.人工耳蜗植入患者常见聋病相关基因突变与内耳畸形的相关性分析[J].中华耳科学杂志，2019,17(5):643-649.

15 Everett LA,Belyantseva IA,Noben-Trauth K,et al.Targeted disruption of mouse Pds provides insight about the inner-ear defects encountered in Pendred syndrome[J].Hum Mol Genet,2001,10(2):153-161.

16 Lu YC,Wu CC,Shen WS,et al.Establishment of a knock-in mouse model with the SLC26A4 c.919-2A>G mutation and characterization of its pathology[J].PLoS One,2011,6(7):e22150.

17 Choi HJ,Lee HJ,Choi JY,et al.DNAJC14 ameliorates inner ear degeneration in the DFNB4 mouse model[J].Mol Ther Methods Clin Dev,2020,17:188-197.

18 赖若沙，谢缤灵，邓慧玲，等.斑马鱼Slc26a4基因敲除品系的构建[J].中华耳科学杂志，2021,19(4):641-646.

19 Hu CJ,Lu YC,Yang TH,et al.Toward the pathogenicity of the SLC26A4 p.C565Y variant using a genetically driven mouse model[J].Int J Mol Sci,2021,22(6):2789.

20 Seok J,Warren HS,Cuenca AG,et al.Genomic responses in mouse models poorly mimic human inflammatory diseases[J].Proc Natl Acad Sci U S A,2013,110(9):3507-3512.

21 Fan N,Chen J,Shang Z,et al.Piglets cloned from induced pluripotent stem cells[J].Cell Res,2013,23(1):162-166.

22 Guo W,Yi H,Ren L,et al.The morphology and electrophysiology of the cochlea of the miniature pig[J].The Anatomical Record,2015,298(3):494-500.

23 Gu X,Jiang QQ,Sun W.Anatomical analysis of vestibular aqueducts in humans and miniature pigs[J].The Anatomical Record,2021,304(8):1811-1819.

24 Zhou X,Xin J,Fan N,et al.Generation of CRISPR/Cas9-mediated gene-targeted pigs via somatic cell nuclear transfer[J].Cell Mol Life Sci,2015,72(6):1175-1184.