M. Kellomäki, H. Niiranen, K. Puumanen, N. Ashammakhi, T. Waris, and P. Törmälä Bioabsorbable scaffolds for guided bone regeneration and generation Biomaterials 21 2000 2495 2505
T. Riley, S. Stolnik, C. Heald, C. Xiong, M. Garnett, and L. Illum Physicochemical evaluation of nanoparticles assembled from poly (lactic acid)-poly (ethylene glycol)(PLA-PEG) block copolymers as drug delivery vehicles Langmuir 17 2001 3168 3174
C.X. Zhang, B. Wang, Y. Chen, F. Cheng, and S.C. Jiang Amphiphilic multiarm star polylactide with hyperbranched polyethylenimine as core: a systematic reinvestigation Polymer 53 2012 3900 3909
R. Sinclair The case for polylactic acid as a commodity packaging plastic J Macromol Sci Part A: Pure Appl Chem 33 1996 585 597
J. Lunt, and A.L. Shafer Polylactic acid polymers from com. Applications in the textiles industry J Ind Textiles 29 2000 191 205
E.T.H. Vink, K.R. Rabago, D.A. Glassner, and P.R. Gruber Applications of life cycle assessment to NatureWorks™ polylactide (PLA) production Polym Degrad Stab 80 2003 403 419
M.H. Huang, S.M. Li, and M. Vert Amphiphilic multiarm star polylactide with hyperbranched polyethylenimine as core: a systematic reinvestigation Polymer 45 2004 8675 8681
S.K. Saha, and H. Tsuji Effects of molecular weight and small amounts of d-lactide units on hydrolytic degradation of poly (l-lactic acid) s Polym Degrad Stab 91 2006 1665 1673
H. Tsuji, and C.A. Del Carpio In vitro hydrolysis of blends from enantiomeric poly (lactide) s. 3. Homocrystallized and amorphous blend films Biomacromolecules 4 2003 7 11
H. Pistner, R. Gutwald, R. Ordung, J. Reuther, and J. Mühling Poly (l-lactide): a long-term degradation study in vivo: I. Biological results Biomaterials 14 1993 671 677
H. Pistner, H. Stallforth, R. Gutwald, J. Mühling, J. Reuther, and C. Michel Poly (l-lactide): a long-term degradation study in vivo: part II: physico-mechanical behaviour of implants Biomaterials 15 1994 439 450
H. Pistner, D.R. Bendi, J. Mühling, and J.F. Reuther Poly (l-lactide): a long-term degradation study in vivo: part III. Analytical characterization Biomaterials 14 1993 291 298
M.A. Paul, C. Delcourt, M. Alexandre, P. Degée, F. Monteverde, and P. Dubois Polylactide/montmorillonite nanocomposites: study of the hydrolytic degradation Polym Degrad Stab 87 2005 535 542
G. Ganjyal, R. Weber, and M. Hanna Laboratory composting of extruded starch acetate and poly lactic acid blended foams Bioresour Technol 98 2007 3176 3179
R. Iovino, R. Zullo, M. Rao, L. Cassar, and L. Gianfreda Biodegradation of poly (lactic acid)/starch/coir biocomposites under controlled composting conditions Polym Degrad Stab 93 2008 147 157
S. Iannace, A. Maffezzoli, G. Leo, and L. Nicolais Influence of crystal and amorphous phase morphology on hydrolytic degradation of PLLA subjected to different processing conditions Polymer 42 2001 3799 3807
R.A. Miller, J.M. Brady, and D.E. Cutright Degradation rates of oral resorbable implants (polylactates and polyglycolates): rate modification with changes in PLA/PGA copolymer ratios J Biomed Mater Res 11 2004 711 719
H. Deng, E. Bilotti, R. Zhang, J. Loos, and T. Peijs Effect of thermal annealing on the electrical conductivity of high-strength bicomponent polymer tapes containing carbon nanofillers Synth Met 160 2010 337 344
M. Shahinpoor, and K.J. Kim Ionic polymer-metal composites: I. Fundamentals Smart Mater Struct 10 2001 819 833
M.H. Al-Saleh, and U. Sundararaj A review of vapor grown carbon nanofiber/polymer conductive composites Carbon 47 2009 2 22
J.R. Wood, Q. Zhao, M.D. Frogley, E.R. Meurs, A.D. Prins, and T. Peijs Carbon nanotubes: from molecular to macroscopic sensors Phys Rev B 62 2000 7571 7575
J.K. Abraham, B. Philip, A. Witchurch, V.K. Varadan, and C.C. Reddy A compact wireless gas sensor using a carbon nanotube/PMMA thin film chemiresistor Smart Mater Struct 13 2004 1045 1049
B. Kumar, M. Castro, and J.-F. Feller Poly (lactic acid)-multi-wall carbon nanotube conductive biopolymer nanocomposite vapour sensors Sens Actuators B: Chem 161 2012 621 628
R. Zhang, M. Baxendale, and T. Peijs Universal resistivity-strain dependence of carbon nanotube/polymer composites Phys Rev B 76 2007 195433-1 195433-5
E. Bilotti, R. Zhang, H. Deng, M. Baxendale, and T. Peijs Fabrication and property prediction of conductive and strain sensing TPU/CNT nanocomposite fibres J Mater Chem 20 2010 9449 9455
N. Ferrer-Anglada, M. Kaempgen, and S. Roth Transparent and flexible carbon nanotube/polypyrrole and carbon nanotube/polyaniline pH sensors Physica Status Solidi (B) 243 2006 3519 3523
P. Pötschke, T. Andres, T. Villmow, S. Pegel, H. Brünig, and K. Kobashi Liquid sensing properties of fibres prepared by melt spinning from poly (lactic acid) containing multi-walled carbon nanotubes Composites Sci Technol 70 2010 343 349
H. Li, and M.A. Huneault Effect of nucleation and plasticization on the crystallization of poly(lactic acid) Polymer 48 2007 6855 6866
M. Hakkarainen, A.-C. Albertsson, and S. Karlsson Weight losses and molecular weight changes correlated with the evolution of hydroxyacids in simulated in vivo degradation of homo-and copolymers of PLA and PGA Polym Degrad Stab 52 1996 283 291
H. Tsuji, and K. Ikarashi In vitro hydrolysis of poly (l-lactide) crystalline residues as extended-chain crystallites: III. Effects of pH and enzyme Polym Degrad Stab 85 2004 647 656
H. Tsuji, and K. Ikarashi In vitro hydrolysis of poly (l-lactide) crystalline residues as extended-chain crystallites: II. Effects of hydrolysis temperature Biomacromolecules 5 2004 1021 1028
J.W. Leenslag, A.J. Pennings, R.R. Bos, F.R. Rozema, and G. Boering Resorbable materials of poly (L-lactide): VII. In vivo and in vitro degradation Biomaterials 8 1987 311 314
S.R. Broadbent, and J.M. Hammersley Percolation processes I. Crystals and mazes Proc Cambridge Philoso Soc 53 1957 629
R. Zhang, H. Deng, R. Valenca, J. Jin, Q. Fu, and E. Bilotti Carbon nanotube polymer coatings for textile yarns with good strain sensing capability Sens Actuators A: Phys 179 2012 83 91
E.T. Thostenson, and T.W. Chou Carbon nanotube networks: sensing of distributed strain and damage for life prediction and self healing Adv Mater 18 2006 2837 2841
K.L. Lasater, and E.T. Thostenson In situ thermoresistive characterization of multifunctional composites of carbon nanotubes Polymer 53 2012 5367 5374
C.-C. Teng, C.-C.M. Ma, Y.-W. Huang, S.-M. Yuen, C.-C. Weng, and C.-H. Chen Effect of MWCNT content on rheological and dynamic mechanical properties of multiwalled carbon nanotube/polypropylene composites Compos Part A: Appl Sci Manuf 39 2008 1869 1875