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  1. 1
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  2. 2
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  3. 3
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  4. 4
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  5. 5
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  6. 6
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  7. 7
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  8. 8
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  9. 9
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  10. 10
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  11. 11
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  12. 12
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  13. 13
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  15. 15
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  16. 16
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  17. 17
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  18. 18
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  19. 19
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  20. 20
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  21. 21
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  23. 23
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  24. 24
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  25. 25
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  26. You have free access to this content26
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  27. 27
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  28. 28
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  29. 29
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  30. 30
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  31. 31
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  32. 32
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  33. 33
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  34. 34
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  35. 35
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  36. 36
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  37. 37
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  38. 38
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  39. 39
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  40. 40
    Jeong-Hun Kang, Riki Toita, Yoshiki Katayama, Bio and nanotechnological strategies for tumor-targeted gene therapy, Biotechnology Advances, 2010, 28, 6, 757

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  41. 41
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  42. 42
    Kumi KAWANO, Yoshie MAITANI, Tumor Permeability of Nanocarriers Observed by Dynamic Contrast-enhanced Magnetic Resonance Imaging, YAKUGAKU ZASSHI, 2010, 130, 12, 1679

    CrossRef

  43. 43
    Seung-Young Lee, Ji-Xin Cheng, Clearance of Nanoparticles During Circulation, Pharmaceutical Sciences Encyclopedia,
  44. 44
    Hiroshi Maeda, Enhanced Permeability and Retention Effect in Relation to Tumor Targeting,
  45. 45
    Gaurav Bajaj, Yoon Yeo, Tumor-Targeted Nanoparticles: State-of-the-Art and Remaining Challenges, Pharmaceutical Sciences Encyclopedia,