PURPOSE: Multipurpose contact lens solution (MPS)/preservative-associated transient corneal hyperfluorescence has been suggested to represent corneal injury. To determine the validity of this assumption, the molecular-level interactions of common disinfectants in soft contact lens MPS and the corneal epithelium using an in vitro model were assessed. METHODS: A liposome-based model of the corneal epithelial surface was developed and used to assess the interactions of polyhexamethylene biguanide (PHMB), polyquaternium-1 (PQ-1), and fluorescein with membrane components and the effects of PHMB and PQ-1 on membrane integrity. The fluorescence anisotropy (a measure of interactions between molecules) was determined. Liposome integrity was assessed by measuring the liposome melting point temperature. RESULTS: Free fluorescein did not associate with the liposome (P>0.4). Both fluorescein-tagged PHMB and PQ-1 associated with liposomes (P<0.002 and P≤0.01, respectively); however, only PHMB induced free fluorescein association with membrane components. At physiological temperature, no significant shift in the melting point temperature was observed when liposomes were exposed to PHMB from 0 to 100 ppm (P>0.05). In contrast, exposure of >7 ppm PQ-1 disrupted the liposomes. CONCLUSIONS: Based on this study, PHMB-to-liposome bilayer interaction is nondestructive, even at concentrations 100 times higher than found in commercially available MPS products. In contrast, PQ-1-to-liposome bilayer interaction led to liposome disruption. This study presents molecular-level evidence to support that preservative-associated transient corneal hyperfluorescence is a benign transient phenomenon and its evaluation clinically may be an ambiguous strategy for determining biocompatibility and cell surface integrity.
PURPOSE: Multipurpose contact lens solution (MPS)/preservative-associated transient corneal hyperfluorescence has been suggested to represent corneal injury. To determine the validity of this assumption, the molecular-level interactions of common disinfectants in soft contact lens MPS and the corneal epithelium using an in vitro model were assessed. METHODS: A liposome-based model of the corneal epithelial surface was developed and used to assess the interactions of polyhexamethylene biguanide (PHMB), polyquaternium-1 (PQ-1), and fluorescein with membrane components and the effects of PHMB and PQ-1 on membrane integrity. The fluorescence anisotropy (a measure of interactions between molecules) was determined. Liposome integrity was assessed by measuring the liposome melting point temperature. RESULTS: Free fluorescein did not associate with the liposome (P>0.4). Both fluorescein-tagged PHMB and PQ-1 associated with liposomes (P<0.002 and P≤0.01, respectively); however, only PHMB induced free fluorescein association with membrane components. At physiological temperature, no significant shift in the melting point temperature was observed when liposomes were exposed to PHMB from 0 to 100 ppm (P>0.05). In contrast, exposure of >7 ppm PQ-1 disrupted the liposomes. CONCLUSIONS: Based on this study, PHMB-to-liposome bilayer interaction is nondestructive, even at concentrations 100 times higher than found in commercially available MPS products. In contrast, PQ-1-to-liposome bilayer interaction led to liposome disruption. This study presents molecular-level evidence to support that preservative-associated transient corneal hyperfluorescence is a benign transient phenomenon and its evaluation clinically may be an ambiguous strategy for determining biocompatibility and cell surface integrity.
Authors: May M Bakkar; Luke Hardaker; Peter March; Philip B Morgan; Carole Maldonado-Codina; Curtis B Dobson Journal: PLoS One Date: 2014-01-28 Impact factor: 3.240