Physicochemical stability of total nutrient admixtures.

The effect of six independent factors on the stability of i.v. nutritional emulsions was studied. Forty-five i.v. nutritional admixtures were prepared, each containing the following: (1) amino acids (range, 2.5-7%), (2) hydrated glucose (range, 5-20%), (3) lipid emulsion (range, 2-5%), (4) monovalent cations (range, 0-150 meq/L), (5) divalent cations (range, 4-20 meq/L), and (6) trivalent cations (range, 0-10 mg of elemental iron/L). Stability assessments included particle-size analysis, pH determination, and visual inspection. Sizing and counting of fat particles was achieved by using light obscuration and dynamic light scatter methods. Light obscuration and visual assessments were performed at 0, 6, 12, 24, and 30 hours. Dynamic light scatter and pH determinations were performed at 0 and 30 hours. Multiple stepwise regression analysis revealed that trivalent cation concentration was the only variable that affected the stability of nutritional emulsions (p < 0.00001), accounting for approximately 60% of the potentially dangerous increases in fat particle sizes observed. In addition, a percentage of large fat particles (> 5 microns in diameter) greater than 0.4% was associated with unstable emulsions. However, this instability was visibly evident only 65% of the time. Changes in mean globule diameter, cream-layer thickness, and pH did not reveal instability in these emulsions. Emulsions in which > 0.4% of the initial fat concentration consists of particles of > 5 microns in diameter are likely to become unstable. Of the six factors studied, the trivalent cation in iron dextran was most disruptive to lipid-based parenteral nutrient admixtures.