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成果统计

合作作者[TOP 5]

  • 杨贝

    合作成果数:67

  • 杨力

    合作成果数:56

  • 黄行许

    合作成果数:45

  • 王丽洁

    合作成果数:25

  • 王潇

    合作成果数:23

访问统计


  总访问量
 3669
  访问来源
    内部: 87
    外部: 3582
    国内: 3357
    国外: 312

  年访问量
 406
  访问来源
    内部: 4
    外部: 402
    国内: 384
    国外: 22

  月访问量
 139
  访问来源
    内部: 4
    外部: 135
    国内: 133
    国外: 6

访问量

访问量

1. Enhanced base editing by co-expression of free uracil DNA glycosyl.. [2862]
2. Efficient generation of mouse models of human diseases via ABE- an.. [1568]
3. Efficient base editing in G/C-rich regions to model androgen insen.. [1373]
4. BE-PLUS: a new base editing tool with broadened editing window and.. [1263]
5. Highly efficient and precise base editing in discarded human tripr.. [1247]
6. Comparison of cytosine base editors and development of the BEable-.. [1238]
7. Base editing with a Cpf1-cytidine deaminase fusion [1148]
8. Loss of Sun2 promotes the progression of prostate cancer by regula.. [1146]
9. Highly efficient prime editing by introducing same-sense mutations.. [1141]
10. Eliminating base-editor-induced genome-wide and transcriptome-wide.. [914]
11. Efficient base editing in methylated regions with a human APOBEC3A.. [881]
12. Cas12a Base Editors Induce Efficient and Specific Editing with Low.. [825]
13. To BE or not to BE, that is the question [736]
14. Breaking bad: The mutagenic effect of DNA repair [732]
15. APOBEC3 induces mutations during repair of CRISPR-Cas9-generated D.. [732]
16. Correction of the Marfan Syndrome Pathogenic FBN1 Mutation by Base.. [670]
17. Knockout of circRNAs by base editing back-splice sites of circular.. [660]
18. One Prime for All Editing [657]
19. Generation of isogenic single and multiplex gene knockout mice by .. [636]
20. Development and Application of Base Editors [611]
21. Gene editing and its applications in biomedicine [584]
22. The Future of Genome Editing [559]
23. Discrete RNA–DNA hybrid cleavage by the EXD2 exonuclease pinpoint.. [551]
24. APOBEC: From mutator to editor [549]
25. 一种包含支架的引导RNA及利用其的遗传编辑的方法 [531]
26. GENOMIC EDITING OF IMPROVED EFFICIENCY AND ACCURACY [481]
27. BASE EDITING SYSTEM AND METHOD [475]
28. Genomic and Transcriptomic Analyses of Prime Editing Guide RNA-Ind.. [460]
29. Base editing of the HBG promoter induces potent fetal hemoglobin e.. [407]
30. 一种融合蛋白在遗传编辑的用途 [403]
31. 一对用于编辑人PCSK9核酸序列的辅助引导RNA//引导RNA [396]
32. FUSION PROTEINS FOR BASE EDITING [392]
33. 一种碱基编辑分子及其用途 [386]
34. Design and application of the transformer base editor in mammalian.. [383]
35. 抑制基因编辑中的非预期突变 [382]
36. CRISPR Adventures in China [376]
37. 一种基因碱基编辑器 [376]
38. 用于碱基编辑的融合蛋白 [367]
39. 一种碱基编辑分子及其用途 [366]
40. Inhibition of unintended mutations in gene editing [366]
41. 用于治疗β-血红蛋白病的基因疗法 [362]
42. GENE THERAPY FOR TREATING BETA-HEMOGLOBINOPATHIES [355]
43. 用于治疗β-血红蛋白病的基因疗法 [352]
44. 提高效率和准确性的基因组编辑 [352]
45. 一对用于编辑人PCSK9核酸序列的辅助引导RNA//引导RNA [347]
46. 提高效率和准确性的基因组编辑 [346]
47. 提高效率和准确性的基因组编辑 [343]
48. No observable guide-RNA-independent off-target mutation induced by.. [339]
49. 基因编辑中非预期突变的抑制 [336]
50. 提高效率和准确性的基因组编辑 [333]
51. FUSION PROTEINS FOR IMPROVED PRECISION IN BASE EDITING [332]
52. 促进人细胞中γ-珠蛋白产生的方法,编码CRISPR相关蛋白(CAS)、核碱基脱.. [323]
53. 提高效率和准确性的基因组编辑 [312]
54. A Tale of Two Moieties: Rapidly Evolving CRISPR/Cas-Based Genome E.. [310]
55. 用于碱基编辑的融合蛋白 [308]
56. 用于提高碱基编辑精度的融合蛋白 [308]
57. 用于治疗β-血红蛋白病的基因疗法 [308]
58. Base editing of organellar DNA with programmable deaminases [298]
59. 基因疗法治疗β-血红蛋白病 [296]
60. 基因编辑中非预期突变的抑制 [294]
61. 提高效率和准确性的基因组编辑 [291]
62. 用于治疗β-血红蛋白病的基因疗法 [290]
63. 用于提高碱基编辑精度的融合蛋白 [288]
64. 基因编辑中非有意突变的抑制 [285]
65. 一种基因碱基编辑器 [284]
66. 抑制基因编辑中的非预期突变 [279]
67. FUSION PROTEINS FOR IMPROVED PRECISION IN BASE EDITING [277]
68. INHIBITION OF UNINTENDED MUTATIONS IN GENE EDITING [276]
69. 一种纳米抗菌材料及其制备方法 [272]
70. FUSION PROTEINS FOR BASE EDITING [263]
71. 基因编辑中非故意突变的抑制 [262]
72. 一种碱基编辑系统及其构建和应用方法 [259]
73. 硅纳米针阵列抗菌材料的制备及其抗菌性能研究 [252]
74. 基因编辑中非故意突变的抑制 [251]
75. 用于治疗β-血红蛋白病的基因疗法 [249]
76. 计算生物学分析在基因组编辑研究中的应用 [246]
77. 用于提高碱基编辑精度的融合蛋白 [246]
78. Prime editor-mediated functional reshaping of ACE2 prevents the en.. [246]
79. 基因编辑中非故意突变的抑制 [245]
80. 基因编辑中非预期突变的抑制 [234]
81. 基因编辑中非故意突变的抑制 [232]
82. Marketing's Role in Promoting the Common Good: A Systematic Examin.. [230]
83. FUSION PROTEINS FOR BASE EDITING [229]
84. 用于碱基编辑的融合蛋白 [224]
85. 碱基编辑技术的发展与应用 [213]
86. 基因编辑中非故意突变的抑制 [211]
87. Expanding genome editing scopes with artificial intelligence [154]
88. Targeted Delivery of mRNA with Polymer-Lipid Nanoparticles for In .. [126]
89. Efficient Genome Editing of Human T Cells with Innovative Transfor.. [120]
90. Innovative Transformer Base Editor (tBE)-Mediated Undetected Off-T.. [119]
91. Development of Best-in-Class Gene Editing Therapy for β-Hemoglo.. [116]
92. Precise Base Editing of Hyperlipidemia-Associated Genes by the Tra.. [104]
93. CRISP相关蛋白(CAS)、核baze脱氨基、单指导RNA(SGRNA)和帮助单指导RNA(.. [95]
94. Specific and efficient RNA A-to-I editing through cleavage of an A.. [73]
95. 高效和特异性的RNA编辑系统 [41]
96. Rapid, Efficient and Durable Fetal Hemoglobin Production Following.. [31]
97. Leveraging base excision repair for efficient adenine base editing.. [29]

下载量

1. Enhanced base editing by co-expression of free uracil DNA glycosyl.. [624]
2. Efficient generation of mouse models of human diseases via ABE- an.. [435]
3. Loss of Sun2 promotes the progression of prostate cancer by regula.. [361]
4. Highly efficient and precise base editing in discarded human tripr.. [360]
5. Comparison of cytosine base editors and development of the BEable-.. [346]
6. Efficient base editing in G/C-rich regions to model androgen insen.. [302]
7. Knockout of circRNAs by base editing back-splice sites of circular.. [243]
8. Highly efficient prime editing by introducing same-sense mutations.. [231]
9. Breaking bad: The mutagenic effect of DNA repair [207]
10. No observable guide-RNA-independent off-target mutation induced by.. [67]
11. BASE EDITING SYSTEM AND METHOD [47]
12. Cas12a Base Editors Induce Efficient and Specific Editing with Low.. [26]
13. One Prime for All Editing [22]
14. Targeted Delivery of mRNA with Polymer-Lipid Nanoparticles for In .. [22]
15. Efficient base editing in methylated regions with a human APOBEC3A.. [14]
16. To BE or not to BE, that is the question [13]
17. CRISPR Adventures in China [12]
18. Base editing with a Cpf1-cytidine deaminase fusion [9]
19. Eliminating base-editor-induced genome-wide and transcriptome-wide.. [9]
20. Discrete RNA–DNA hybrid cleavage by the EXD2 exonuclease pinpoint.. [8]
21. Development and Application of Base Editors [7]
22. Design and application of the transformer base editor in mammalian.. [7]
23. Prime editor-mediated functional reshaping of ACE2 prevents the en.. [6]
24. 提高效率和准确性的基因组编辑 [6]
25. Specific and efficient RNA A-to-I editing through cleavage of an A.. [6]
26. Base editing of the HBG promoter induces potent fetal hemoglobin e.. [5]
27. APOBEC3 induces mutations during repair of CRISPR-Cas9-generated D.. [4]
28. The Future of Genome Editing [4]
29. 用于治疗β-血红蛋白病的基因疗法 [4]
30. 用于治疗β-血红蛋白病的基因疗法 [4]
31. BE-PLUS: a new base editing tool with broadened editing window and.. [3]
32. Generation of isogenic single and multiplex gene knockout mice by .. [3]
33. Correction of the Marfan Syndrome Pathogenic FBN1 Mutation by Base.. [3]
34. Base editing of organellar DNA with programmable deaminases [3]
35. 提高效率和准确性的基因组编辑 [3]
36. Leveraging base excision repair for efficient adenine base editing.. [3]
37. A Tale of Two Moieties: Rapidly Evolving CRISPR/Cas-Based Genome E.. [2]
38. 抑制基因编辑中的非预期突变 [2]
39. 基因编辑中非故意突变的抑制 [2]
40. 一种碱基编辑系统及其构建和应用方法 [1]
41. 一种纳米抗菌材料及其制备方法 [1]
42. Genomic and Transcriptomic Analyses of Prime Editing Guide RNA-Ind.. [1]
43. Gene editing and its applications in biomedicine [1]
44. GENE THERAPY FOR TREATING BETA-HEMOGLOBINOPATHIES [1]
45. FUSION PROTEINS FOR IMPROVED PRECISION IN BASE EDITING [1]
46. 基因编辑中非预期突变的抑制 [1]
47. 用于提高碱基编辑精度的融合蛋白 [1]
48. 一种融合蛋白在遗传编辑的用途 [1]
49. 抑制基因编辑中的非预期突变 [1]
50. 用于治疗β-血红蛋白病的基因疗法 [1]
51. 促进人细胞中γ-珠蛋白产生的方法,编码CRISPR相关蛋白(CAS)、核碱基脱.. [1]
52. 一对用于编辑人PCSK9核酸序列的辅助引导RNA//引导RNA [1]
53. 提高效率和准确性的基因组编辑 [1]
54. 用于提高碱基编辑精度的融合蛋白 [1]