TY - JOUR
T1 - Key functions in polymer carriers for intestinal absorption of insulin
AU - Nakamura, Koji
AU - Morishita, Mariko
AU - Ehara, Junpei
AU - Onuki, Yoshinori
AU - Yamagata, Tetsuo
AU - Kamei, Noriyasu
AU - Lowman, Anthony M.
AU - Peppas, Nicholaos A.
AU - Takayma, Kozo
PY - 2008/4/16
Y1 - 2008/4/16
N2 - This work aimed to clarify the relationship between polymer function and insulin absorption, and to evaluate the optimized preparative formulation predicted from this relationship. Insulin-loaded polymer (ILP) carrier systems were prepared following a two-factor composite second-order spherical experimental design. To investigate the polymer function, we evaluated its insulin release, bioadhesiveness, and protective effect. Each ILP was administered intestinally, and glucose reduction was monitored as the pharmacological effect. Based on these data, an optimized formulation was predicted and how the polymer function affects insulin absorption was clarified by multivariate spline (MVS) interpolation. A greater pharmacological effect was apparent in ILPs with a smaller particle size and loaded with more insulin. The pharmacological effect predicted by MVS after the administration of ILP made under optimized preparative conditions was almost identical to the observed effect. Moreover, MVS clarified the relationship between the polymer function and the pharmacological effect. These results supported that MVS can be an effective tool with which to approximate the relationship between the function of a dosage form and its absorption, and to explore the optimized preparative conditions.
AB - This work aimed to clarify the relationship between polymer function and insulin absorption, and to evaluate the optimized preparative formulation predicted from this relationship. Insulin-loaded polymer (ILP) carrier systems were prepared following a two-factor composite second-order spherical experimental design. To investigate the polymer function, we evaluated its insulin release, bioadhesiveness, and protective effect. Each ILP was administered intestinally, and glucose reduction was monitored as the pharmacological effect. Based on these data, an optimized formulation was predicted and how the polymer function affects insulin absorption was clarified by multivariate spline (MVS) interpolation. A greater pharmacological effect was apparent in ILPs with a smaller particle size and loaded with more insulin. The pharmacological effect predicted by MVS after the administration of ILP made under optimized preparative conditions was almost identical to the observed effect. Moreover, MVS clarified the relationship between the polymer function and the pharmacological effect. These results supported that MVS can be an effective tool with which to approximate the relationship between the function of a dosage form and its absorption, and to explore the optimized preparative conditions.
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U2 - 10.1016/j.ijpharm.2007.10.050
DO - 10.1016/j.ijpharm.2007.10.050
M3 - Article
C2 - 18093760
AN - SCOPUS:40849147314
SN - 0378-5173
VL - 354
SP - 135
EP - 142
JO - International Journal of Pharmaceutics
JF - International Journal of Pharmaceutics
IS - 1-2
ER -