Scalable production of core–shell nanoparticles by flash nanocomplexation to enhance mucosal transport for oral delivery of insulin

Flash Nanocomplexation (FNC) as a scalable manufacturing method to facilitate successful clinical translation of protein therapeutics.

Simultaneous quantification of mannitol, 3-O-methyl glucose, and lactulose in urine by HPLC with pulsed electrochemical detection, for use in studies of intestinal permeability

The percentage of an oral dose of mannitol, 3-O-methyl glucose, and lactulose excreted in urine is used in noninvasive investigation of active and passive intestinal mucosal transport. We developed a high-pressure liquid-chromatographic method involving anion exchange and pulsed electrochemical detection that allows the simultaneous determination of all three sugar probes in urine. Sample preparation is simple: diluting, mixing with internal standard (melibiose), and desalting. With use of a Dionex 250 x 40 mm Carbopac PA-1 column and elution with an isocratic mixture of 120 mmol/L NaOH and 0.5 mmol/L zinc acetate, all sugars were resolved within 10 min. The standard curve of the method is linear to the following concentrations: mannitol 125 mg/L, 3-O-methyl glucose 300 mg/L, and lactulose 40 mg/L. The minimal detectable concentration of lactulose is 0.4 mg/L. Analytical recovery of the sugars is between 89.0% and 99.5%. The precision of estimation (CV) ranges from 1.76% to 5.6% overall. Reference intervals were established from results for 28 healthy children. The method is adaptable for the study of carbohydrates at low concentrations in other biological fluids.

Transport of albumin by the rabbit trachea in vitro

The rabbit whole trachea was mounted in vitro in an organ bath containing Krebs-Henseleit (KH) solution. When the trachea was air filled there was no resting secretion and none was induced by methacholine (0.02 mM). Histology showed that the trachea has very few submucosal glands. When the trachea was filled with KH, with fluorescent bovine serum albumin in the surrounding KH solution, the rate of transport of albumin into the lumen was measured. Methacholine (0.02 mM) and phenylephrine (0.1 mM) more than doubled the output of albumin, and albuterol (0.1 mM) increased it more than fourfold. Cooling the preparation to 4 degrees C decreased the spontaneous output of albumin to less than one-half control and abolished the increase in output due to albuterol. Addition of sodium cyanide (1 mM) to the preparation abolished the increase in albumin transport due to albuterol. Serosal-to-mucosal transport of fluorescent dextran (mol wt 70,000) was less than one-third that of albumin and was not enhanced by methacholine, phenylephrine, or albuterol. Lysozyme output, an index of serous cell secretion, was barely detectable in controls and was not enhanced by any of the drugs. We conclude that the rabbit trachea has no measurable submucosal gland secretion and that it can actively transport albumin into the lumen via the epithelium. The transport rate is enhanced by methacholine, phenylephrine, and especially by albuterol.