2018
DOI: 10.1016/j.addr.2017.12.002
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Technological strategies to estimate and control diffusive passage times through the mucus barrier in mucosal drug delivery

Abstract: In mucosal drug delivery, two design goals are desirable: 1) insure drug passage through the mucosal barrier to the epithelium prior to drug removal from the respective organ via mucus clearance; and 2) design carrier particles to achieve a prescribed arrival time and drug uptake schedule at the epithelium. Both goals are achievable if one can control "one-sided" diffusive passage times of drug carrier particles: from deposition at the mucus interface, through the mucosal barrier, to the epithelium. The passag… Show more

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Cited by 42 publications
(29 citation statements)
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References 117 publications
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“…Due to the hydrophobic domains and the negatively charged sialic acid and sulphate groups in the mucin glycoprotein, the mucus also creates an interactive barrier that limits drug diffusion. Moreover, since mucus is continuously produced, secreted, shed, and discarded [ 17 ], molecules that fail to penetrate the mucus layer are eventually removed by mucus clearance before they can reach the epithelial cells [ 18 ]. The pore size between the mucus mesh network is around 20 to 1800 nm, varying greatly between different sites and disease states [ 15 ].…”
Section: Transmucosal Drug Deliverymentioning
confidence: 99%
See 1 more Smart Citation
“…Due to the hydrophobic domains and the negatively charged sialic acid and sulphate groups in the mucin glycoprotein, the mucus also creates an interactive barrier that limits drug diffusion. Moreover, since mucus is continuously produced, secreted, shed, and discarded [ 17 ], molecules that fail to penetrate the mucus layer are eventually removed by mucus clearance before they can reach the epithelial cells [ 18 ]. The pore size between the mucus mesh network is around 20 to 1800 nm, varying greatly between different sites and disease states [ 15 ].…”
Section: Transmucosal Drug Deliverymentioning
confidence: 99%
“…In general, small molecules that have minimal interaction with the mucus networks (i.e. molecules with a hydrophilic surface and electrically neutral) are more likely to diffuse across the mucus barrier successfully [ 18 ].…”
Section: Transmucosal Drug Deliverymentioning
confidence: 99%
“…Design of carriers should take into account their mobility in viscoelastic mucus toward mucosa lining the inner part of the small intestine and colon. Diffusion of particles in mucus strongly depends on their diameters and adhesive interactions with molecules constituting the mucus gel [ 2 ]. Nanoparticles (i.e., particles with equivalent diameters ranging from approximately 1–100 nm [ 3 ] which do not bind to mucus by physicochemical interactions diffuse by standard Brownian motion.…”
Section: Introductionmentioning
confidence: 99%
“…Small microparticles (microparticles are defined as particles with equivalent diameters in the range from about 0.1–100 nm [ 3 ]) with diameter of the order of mucus gel pores (about 0.2 μm) which are chemically inert toward mucus experience significant hindrance from the gel mesh. Their movements are correlated with movements of mucus chains [ 2 ]. Movement of larger (>0.5 μm) microparticles which are chemically inert toward mucus depends not only on the local fluctuations of mucus chains but to a great extent on mucus movements in the larger scale.…”
Section: Introductionmentioning
confidence: 99%
“…18,19 Chitosan and hyaluronic acid are often used as mucoadhesive coatings. 20 Poly(ethylene glycol) is widely used for "stealth" surface modification, [21][22][23][24] and other candidates as mucus-penetrating coatings have recently been reviewed. 25 Understanding the interactions between coated particles and mucus biobarriers can help design efficient drug carriers for inhalation, 26 ocular, 20 transnasal, 27 vaginal, 28 and oral 16,29 administration.…”
Section: Introductionmentioning
confidence: 99%