1 Li JN,Chen S,Zhai L,et al.The advances in hearing rehabilitation and cochlear implants in China[J].Ear Hear,2017,38:647.

2 Feng G,Ingvalson EM,Grieco-Calub TM,et al.Neural preservation underlies speech improvement from auditory deprivation in young cochlear implant recipients[J].Proc Natl Acad Sci USA,2018,115:E1022.

3 Sharma A,Glick H,Deeves E,et al.The P1 biomarker for assessing cortical maturation in pediatric hearing loss:a review[J].Otorinolaringologia,2015,65:103.

4 Niparko JK,Tobey EA,Thal DJ,et al.Spoken language development in children following cochlear implantation[J].JAMA,2010,303:1498.

5 Dettman SJ,Dowell RC,Choo D,et al.Long-term communication outcomes for children receiving cochlear implants younger than 12 months:a multicenter study[J].Otology & Neurotology,2016,37:e82.

6 Niu H,He Y.Resting-state functional brain connectivity:lessons from functional near-infrared spectroscopy[J].Neuroscientist,2014,20:173.

7 Lu CM,Zhang YJ,Biswal BB,et al.Use of fNIRS to assess resting state functional connectivity[J].J Neurosci Methods,2010,186:242.

8 中华人民共和国卫生部.新生儿听力筛查技术规范【卫妇社发[2010]96号】[J].中国儿童保健杂志,2011,19:574.

9 American Academy of Pediatrics,Joint Commitee on Infant Hearing.Year 2007 position statement:principles and guidelines for early hearing detection and intervention programs[J].Pediatrics,2007,120:898.

10 Wang D,Buckner RL,Liu H.Functional specialization in the human brain estimated by intrinsic hemispheric interaction[J].J Neurosci,2014,34:12341.

11 Zhang H,Lu N,Feng C,et al.On fitting generalized linear mixed-effects models for binary responses using different statistical packages[J].Statistics in Medicine,2011,30:2562.

12 Clark-Gambelunghe MB,Clark DA.Sensory development[J].Pediatr Clin North Am,2015,62:367.

13 张畅芯.早期听觉剥夺后的大脑可塑性:来自先天性听力障碍群体的证据[J].心理科学进展,2019,27:278.

14 Olds C,Pollonini L,Abaya H,et al.Cortical activation patterns correlate with speech understanding after cochlear implantation[J].Ear Hear,2016,37:e160.

15 Bisconti S,Shulkin M,Hu X,et al.Functional near-infrared spectroscopy brain imaging investigation of phonological awareness and passage comprehension abilities in adult recipients of cochlear implants[J].Journal of Speech,Language,and Hearing Research,2016,59:239.

16 White BR,Snyder AZ,Cohen AL,et al.Resting-state functional connectivity in the human brain revealed with diffuse optical tomography[J].NeuroImage,2009,47:148.

17 Molavi B,May L,Gervain J,et al.Analyzing the resting state functional connectivity in the human language system using near infrared spectroscopy[J].Front Hum Neurosci,2013,7:921.

18 Zhang YJ,Lu CM,Biswal BB,et al.Detecting resting-state functional connectivity in the language system using functional near-infrared spectroscopy[J].J Biomed Opt,2010,15:047003.

19 Wiper ML.Evolutionary and mechanistic drivers of laterality:a review and new synthesis[J].Laterality,2017,22:740.

20 Hermundstad AM,Bassett DS,Brown KS,et al.Structural foundations of resting-state and task-based functional connectivity in the human brain[J].Proc Natl Acad Sci USA,2013,110:6169.

21 Gotts SJ,Jo HJ,Wallace GL,et al.Two distinct forms of functional lateralization in the human brain[J].Proc Natl Acad Sci USA,2013,110:E3435.

22 Kral A,Yusuf PA,Land R.Higher-order auditory areas in congenital deafness:top-down interactions and corticocortical decoupling[J].Hear Res,2017,343:50.

23 Sporns O.Network attributes for segregation and integration in the human brain[J].Current Opinion in Neurobiology,2013,23:162.

24 Stolzberg D,Butler BE,Lomber SG.Effects of neonatal deafness on resting-state functional network connectivity[J].Neuroimage,2018,165:69.

25 Peelle JE,Johnsrude IS,Davis MH.Hierarchical processing for speech in human auditory cortex and beyond[J].Front Hum Neurosci,2010,4:51.