Nanoscale modulation of the pore dimensions, size distribution and structure of a new polysulfone-based high-flux dialysis membrane.

Current haemodialysis therapy modalities such as haemodiafiltration enhance the removal of larger uraemic solutes from the blood of patients on end-stage renal disease. A number of clinical investigations have demonstrated the clinical benefits of such therapies in contributing towards better patient survival rates and an improved quality of life. A fundamental prerequisite to the application of convective treatment modalities is the availability of appropriate, technologically-advanced high-flux dialysis membranes that are able to eliminate larger uraemic substances with high efficiency but without causing an excessive leakage of useful proteins. A new membrane, Helixone, has been developed specifically to meet the present-day requirements of high-flux dialysis and haemodiafiltration therapies involving large substitution rates. The application of nanotechnology fabrication principles and procedures has enabled the development of a membrane having highly-defined inner, separating layer surface structures that offer minimal resistance to the removal of large molecular weight substances across the membrane; for the first time, pore size dimensions, pore size distribution and pore geometry have been modulated and controlled at the nanoscale level for Helixone. This paper describes the characterisation of the essential structure- and permeation-related parameters of the new membrane using a number of physical analytical techniques.