FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1570502376> ?p ?o ?g. }

• W1570502376 abstract "Medical-profession-accepted and the US Food and Drug Administration (FDA)-approved biodegradable polymers have been used for tissue engineering applications over the last two decades due to their good biocompatibility and acceptable biodegradation properties. Poly(L-lactide) (PLLA) is a linear aliphatic biodegradable polymer and has been widely studied for use as a scaffolding material for human body tissue regeneration (Wei and Ma 2004; Chen, Mak et al. 2006; Wang 2006). The enzymatic and non-enzymatic hydrolysis rate of PLLA strongly depends on its chemical properties (such as molecular weight and weight distribution) and physical properties (such as crystallinity and morphology). Crystallinity plays an important role in the degradation behavior of biodegradable polymers. It is well known that the crystallinity and morphology of semicrystalline polymers such as PLLA are greatly influenced by their thermal history. Therefore, the crystallization kinetics of PLLA should be carefully studied and correlated to its processing method as it forms a basis for the interpretation of the scaffold properties. The isothermal bulk crystallization kinetics of PLLA has been studied by a number of research groups, covering a temperature range from 70 to 165 °C (Marega, Marigo et al. 1992; Iannace and Nicolais 1997; Miyata and Masuko 1998; Di Lorenzo 2005). But only a few studies were conducted on the non-isothermal crystallization kinetics of neat PLLA. Miyata and Masuko (1998) reported that PLLA could not crystallize and remained amorphous when the cooling rate was higher than 10 °C/min. The knowledge on non-isothermal crystallization kinetics is useful for modelling real industrial processes such as cast film extrusion, which generally takes place at a nonconstant cooling rate (Piorkowska, Galeski et al. 2006). Particulate bioceramic reinforced polymer composites can combine the strength and stiffness of bioactive inorganic fillers with the flexibility and toughness of biodegradable organic matrices. Carbonated hydroxyapatite (CHAp) is a desirable bioactive material for bone substitution as it is bioresorbable and also more bioactive in vivo than stoichiometric hydroxyapatite. PLLA/CHAp nanocomposite has been developed and used for constructing bone tissue engineering scaffolds through selective laser sintering (SLS) (Zhou, Lee et al. 2007; Zhou, Lee et al. 2008). In the SLS process, the laser beam selectively fuses" @default.
• W1570502376 created "2016-06-24" @default.
• W1570502376 creator A5015102287 @default.
• W1570502376 creator A5028288124 @default.
• W1570502376 creator A5070577965 @default.
• W1570502376 creator A5070725173 @default.
• W1570502376 date "2011-03-22" @default.
• W1570502376 modified "2023-10-04" @default.
• W1570502376 title "Isothermal and Non-isothermal Crystallization Kinetics of Poly(L-Lactide)/Carbonated Hydroxyapatite Nanocomposite Microspheres" @default.
• W1570502376 cites W1535269427 @default.
• W1570502376 cites W1650538669 @default.
• W1570502376 cites W1672997411 @default.
• W1570502376 cites W18923716 @default.
• W1570502376 cites W1967460998 @default.
• W1570502376 cites W1969366839 @default.
• W1570502376 cites W1969945203 @default.
• W1570502376 cites W1972120195 @default.
• W1570502376 cites W1972199581 @default.
• W1570502376 cites W1975590279 @default.
• W1570502376 cites W1980586199 @default.
• W1570502376 cites W1981814498 @default.
• W1570502376 cites W1990403850 @default.
• W1570502376 cites W1995698092 @default.
• W1570502376 cites W1998137632 @default.
• W1570502376 cites W2003310410 @default.
• W1570502376 cites W2008263050 @default.
• W1570502376 cites W2013673934 @default.
• W1570502376 cites W2017209567 @default.
• W1570502376 cites W2021790237 @default.
• W1570502376 cites W2023668329 @default.
• W1570502376 cites W2032590228 @default.
• W1570502376 cites W2034162624 @default.
• W1570502376 cites W2037792472 @default.
• W1570502376 cites W2039878600 @default.
• W1570502376 cites W2043824639 @default.
• W1570502376 cites W2044553856 @default.
• W1570502376 cites W2046681894 @default.
• W1570502376 cites W2050080016 @default.
• W1570502376 cites W2050553635 @default.
• W1570502376 cites W2053702437 @default.
• W1570502376 cites W2053725265 @default.
• W1570502376 cites W2053929524 @default.
• W1570502376 cites W2054823052 @default.
• W1570502376 cites W2057525894 @default.
• W1570502376 cites W2058948226 @default.
• W1570502376 cites W2063626250 @default.
• W1570502376 cites W2065168696 @default.
• W1570502376 cites W2065959162 @default.
• W1570502376 cites W2070018815 @default.
• W1570502376 cites W2070986076 @default.
• W1570502376 cites W2072213552 @default.
• W1570502376 cites W2072374156 @default.
• W1570502376 cites W2084068309 @default.
• W1570502376 cites W2084777440 @default.
• W1570502376 cites W2085751190 @default.
• W1570502376 cites W2090260002 @default.
• W1570502376 cites W2091302273 @default.
• W1570502376 cites W2111696991 @default.
• W1570502376 cites W2118325297 @default.
• W1570502376 cites W2127575919 @default.
• W1570502376 cites W2158595960 @default.
• W1570502376 cites W2160071582 @default.
• W1570502376 cites W2162152286 @default.
• W1570502376 cites W2162458814 @default.
• W1570502376 cites W2168647986 @default.
• W1570502376 cites W2486210776 @default.
• W1570502376 cites W2490107154 @default.
• W1570502376 cites W3022801169 @default.
• W1570502376 cites W30751685 @default.
• W1570502376 cites W1990395124 @default.
• W1570502376 doi "https://doi.org/10.5772/14715" @default.
• W1570502376 hasPublicationYear "2011" @default.
• W1570502376 type Work @default.
• W1570502376 sameAs 1570502376 @default.
• W1570502376 citedByCount "4" @default.
• W1570502376 countsByYear W15705023762014 @default.
• W1570502376 countsByYear W15705023762015 @default.
• W1570502376 countsByYear W15705023762017 @default.
• W1570502376 countsByYear W15705023762018 @default.
• W1570502376 crossrefType "book-chapter" @default.
• W1570502376 hasAuthorship W1570502376A5015102287 @default.
• W1570502376 hasAuthorship W1570502376A5028288124 @default.
• W1570502376 hasAuthorship W1570502376A5070577965 @default.
• W1570502376 hasAuthorship W1570502376A5070725173 @default.
• W1570502376 hasBestOaLocation W15705023761 @default.
• W1570502376 hasConcept C121332964 @default.
• W1570502376 hasConcept C127413603 @default.
• W1570502376 hasConcept C133347239 @default.
• W1570502376 hasConcept C148898269 @default.
• W1570502376 hasConcept C159985019 @default.
• W1570502376 hasConcept C188027245 @default.
• W1570502376 hasConcept C189942447 @default.
• W1570502376 hasConcept C192562407 @default.
• W1570502376 hasConcept C203036418 @default.
• W1570502376 hasConcept C42360764 @default.
• W1570502376 hasConcept C62520636 @default.
• W1570502376 hasConcept C92880739 @default.
• W1570502376 hasConcept C97355855 @default.
• W1570502376 hasConceptScore W1570502376C121332964 @default.
• W1570502376 hasConceptScore W1570502376C127413603 @default.

• next