Preparation and printability of ultrashort self-assembling peptide nanoparticles
               biomaterials.2014.04.102.                           Self-assemble  into Diverse Nanostructures:  Morphological
           26.  Loo Y, Lakshmanan A, Ni M, et al., 2010, Peptide Bioink:   Evaluation  and  Potential  Implications.  Int  J  Mol  Sci,
               Self-assembling  Nanofibrous  Scaffolds  for  3d  Organotypic   12:5736-46. DOI 10.3390/ijms12095736.
               Cultures.  Nano Lett,  15:6919-25.  DOI  10.1021/acs.  34.  Loo  Y,  Zhang  S,  Hauser  CAE,  2012,  From  Short
               nanolett.5b02859.                                   Peptides  to  Nanofibers  to  Macromolecular  Assemblies  in
           27.  Sundaramurthi D, Rauf S, Hauser CAE, 2016, 3D Bioprinting   Biomedicine.  Biotech  Adv,  30:593-603.  DOI  10.1016/j.
               Technology  for  Regenerative  Medicine Applications.  Int J   biotechadv.2011.10.004.
               Bioprinting, 2:9-16. DOI 10.18063/ijb.2016.02.010.  35.  Cui  H,  Webber  M,  Stupp  S,  2010,  Self-Assembly  of
           28.  Loo  Y,  Hauser  CAE,  2016,  Bioprinting  Synthetic   Peptide  Amphiphiles:  From  Molecules  to  Nanostrucutres
               Self-assembling   Peptide   Hydrogels   for   Biomedical   to  Biomaterials.  Biopolymers,  94:1-18.  DOI  10.1002/
               Applications.   Biomed  Mater,   11:114103.   DOI   bip.21328.
               10.1088/1748-6041/11/1/014103.                  36.  Lakshmanan A,  Zhang  S,  Hauser  CAE,  2012,  Short  Self-
           29.  Khan Z, Kahin K, Rauf S, et al., 2019, Optimization of a 3D   assembling  Peptides as Building Blocks for Modern
               Bioprinting Process using Ultrashort Peptide Bioinks. Int J   Nanodevices.  Trends Biotech,  30:155-65.  DOI  10.1016/j.
               Bioprinting, 5(1):173. DOI 10.18063/ijb.v5i1.173.   tibtech.2011.11.001.
           30.  Kahin K, Khan Z, Albagami M, et al., 2019, Development of   37.  Hauser  CAE,  Zhang  S,  2010,  Designer  Self-assembling
               a Robotic 3D Bioprinting and Microfluidic Pumping System   Peptide  Nanofiber  Biological  Materials.  Chem Soc Rev,
               for Tissue and Organ Engineering. Proc SPIE, 17:108750Q.   39:2780-90. DOI 10.1039/b921448h.
               Doi 10.1117/12.2507237.                         38.  Reithofer  MR,  Chan  KH,  Lakshmanan  A,  et al.,  2014,
           31.  Zhao X, Pan F, Xu H, et al., 2010, Molecular Self-assembly   Ligation of Anti-cancer Drugs to Self-assembling Ultrashort
               and  Applications  of  Designer  Peptide  Amphiphiles.  Chem   Peptides by Click Chemistry for Localized Therapy. Chem
               Soc Rev, 39:3480-98.                                Sci, 5:625-30. DOI 10.1039/c3sc51930a.
           32.  Versluis  F,  Marsden  HR,  Kros  A,  2010,  Power  Struggles   39.  Liu  X,  Huang  J,  Chen  T,  et al.,  2008,  Yamanaka  Factors
               in  Peptide-amphiphile  Nanostructures.  Chem  Soc  Rev,   Critically  Regulate  the  Developmental  Signaling  Network
               39:3434-44. DOI 10.1039/b919446k.                   in Mouse Embryonic Stem Cells. Cell Res, 18(12):1177-89.
           33.  Lakshmanan  A,  Hauser  CAE,  2011,  Ultrasmall  Peptides   DOI 10.1038/cr.2008.309.






































           116                         International Journal of Bioprinting (2019)–Volume 5, Issue 2