Separation of Peptides with Forward Osmosis Biomimetic Membranes
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Separation of Peptides with Forward Osmosis Biomimetic Membranes. / Bajraktari, Niada; Madsen, Henrik T; Gruber, Mathias F; Truelsen, Sigurd; Jensen, Elzbieta L; Jensen, Henrik; Hélix-Nielsen, Claus.
In: Membranes, Vol. 6, 46, 15.11.2016, p. 1-12.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - Separation of Peptides with Forward Osmosis Biomimetic Membranes
AU - Bajraktari, Niada
AU - Madsen, Henrik T
AU - Gruber, Mathias F
AU - Truelsen, Sigurd
AU - Jensen, Elzbieta L
AU - Jensen, Henrik
AU - Hélix-Nielsen, Claus
PY - 2016/11/15
Y1 - 2016/11/15
N2 - Forward osmosis (FO) membranes have gained interest in several disciplines for the rejection and concentration of various molecules. One application area for FO membranes that is becoming increasingly popular is the use of the membranes to concentrate or dilute high value compound solutions such as pharmaceuticals. It is crucial in such settings to control the transport over the membrane to avoid losses of valuable compounds, but little is known about the rejection and transport mechanisms of larger biomolecules with often flexible conformations. In this study, transport of two chemically similar peptides with molecular weight (Mw) of 375 and 692 Da across a thin film composite Aquaporin Inside™ Membrane (AIM) FO membrane was investigated. Despite the relative large size, both peptides were able to permeate the dense active layer of the AIM membrane and the transport mechanism was determined to be diffusion-based. Interestingly, the membrane permeability increased 3.65 times for the 692 Da peptide (1.39 × 10(-12) m²·s(-1)) compared to the 375 Da peptide (0.38 × 10(-12) m²·s(-1)). This increase thus occurs for an 85% increase in Mw but only for a 34% increase in peptide radius of gyration (Rg) as determined from molecular dynamics (MD) simulations. This suggests that Rg is a strong influencing factor for membrane permeability. Thus, an increased Rg reflects the larger peptide chains ability to sample a larger conformational space when interacting with the nanostructured active layer increasing the likelihood for permeation.
AB - Forward osmosis (FO) membranes have gained interest in several disciplines for the rejection and concentration of various molecules. One application area for FO membranes that is becoming increasingly popular is the use of the membranes to concentrate or dilute high value compound solutions such as pharmaceuticals. It is crucial in such settings to control the transport over the membrane to avoid losses of valuable compounds, but little is known about the rejection and transport mechanisms of larger biomolecules with often flexible conformations. In this study, transport of two chemically similar peptides with molecular weight (Mw) of 375 and 692 Da across a thin film composite Aquaporin Inside™ Membrane (AIM) FO membrane was investigated. Despite the relative large size, both peptides were able to permeate the dense active layer of the AIM membrane and the transport mechanism was determined to be diffusion-based. Interestingly, the membrane permeability increased 3.65 times for the 692 Da peptide (1.39 × 10(-12) m²·s(-1)) compared to the 375 Da peptide (0.38 × 10(-12) m²·s(-1)). This increase thus occurs for an 85% increase in Mw but only for a 34% increase in peptide radius of gyration (Rg) as determined from molecular dynamics (MD) simulations. This suggests that Rg is a strong influencing factor for membrane permeability. Thus, an increased Rg reflects the larger peptide chains ability to sample a larger conformational space when interacting with the nanostructured active layer increasing the likelihood for permeation.
U2 - 10.3390/membranes6040046
DO - 10.3390/membranes6040046
M3 - Journal article
C2 - 27854275
VL - 6
SP - 1
EP - 12
JO - Membranes
JF - Membranes
SN - 2077-0375
M1 - 46
ER -
ID: 169356591