1. Nicolini C., Nanogenomics in Medicine, WIREs Nanomedicine & Nanobiotechnology 2, 59-76, 2010.
  2. Nicolini C., LaBaer J., Nanotechnology applications of Nucleic Acid Programmable Protein Arrays, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology Volume 2, Chapter 1, pp. 1-29,   2010, London - New York - Singapore.
  3. Sivozhelezov V., Spera R., Giacomelli L., Hainsworth E., LaBaer J., Bragazzi N.L., Nicolini C., Bioinformatics and Fluorescence DNASER for NAPPA studies on cell transformation and cell cycle, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 2, pp. 31-59,  2010.
  4. Spera R., Badino F., Hainsworth E., Fuentes M., Srivastava, S., LaBaer J., Nicolini C., Label-free detection of NAPPA via mass spectrometry, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 3, pp. 61-78,  2010.
  5. Adami M., Sallam S., Eggenhoffner R., Sartore M., Hainsworth E., LaBaer J., Nicolini C., Label-free NAPPA via nanogravimetry, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 4, pp. 95-108,  2010.
  6. Stura E., Larosa C., Bezerra Correia Terencio T., Hainsworth E., Ramachandran N., LaBaer J., Nicolini C., Label-free NAPPA: Anodic Porous Alumina, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore Volume 2, Chapter 5, pp. 95-108, 2010.
  7. Sartore M., Eggenhoffner R., Bezerra Correia Terencio T., Stura E., Hainsworth, LaBaer J., Nicolini C., Label-free detection of NAPPA via atomic force microscopy, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 6, pp. 109-120,  2010.
  8. Pechkova E., Chong S., Tripathi S., Nicolini C., Cell free expression and APA for NAPPA and protein crystallography, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 7, pp. 121-147, 2010.
  9. Spera R., Nicolini C., Overall proteome alterations during reverse transformaton of growing CHO-K1 cells, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 9, pp. 183-228, 2010.
  10. Danger R., Soulillou J.P: Brouard S., Nicolini C., Organ transplants and gene microarrays, in Functional Proteomics and Nanotechnology-based Microarrays, (Eds. Nicolini C., LaBaer J.) Pan Stanford Series on Nanobiotechnology, London - New York - Singapore, Volume 2, Chapter 10, pp. 229-256, 2010.
  11. Nicolini C., Pechkova E., An overview of nanotechnology-based functional proteomics fro cancer and cell cycle progression, Anticancer Research 30, 2073-2080, 2010.
  12. Nicolini C., Pechkova E., Nanoproteomics for nanomedicine, Nanomedicine 5, 677-682, 2010.
  13. Pechkova E., Nicolini C., Domain organization and properties of LB lysozyme crystals down to submicron size, Anticancer Research 30, 2745-2748, 2010.
  14. Pechkova E., Gebhardt R., Riekel C., Nicolini C., In situ microGISAXS: I. Experimental setup for submicron study of protein nucleation and growth, Biophysical Journal 99, 1256-1261, 2010.
  15. Gebhardt R., Pechkova E., Riekel C., Nicolini C., In situ microGISAXS: II. Thaumatin crystal growth kinetic, Biophysical Journal 99, 1262-1267, 2010.
  16. Jovanovic V., Giacomelli L., Sivozhelezov V., Degauque N., Lair D., Soulillou J.P., Pechkova E., Nicolini C., Brouard S., AKT1 leader gene and downstream targets are involved in a rat model of kidney allograft tolerance, Journal of Cellular Biochemistry 111, 709-719, 2010.