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Existence of advanced glycation / lipoxidation end-products in parenteral nutrition solutions and effects of infusion conditions on their levels

Abstract

Infusion solutions must be stable from the production stage until the infusion stage. Some infusion fluids contain degradation products, known as advanced glycation end products (AGEs); however, it is unknown whether AGEs exist in parenteral nutrition solutions. We aimed to investigate this question and test the effect of infusion conditions on AGE formation in parenteral nutrition solution. Nine parenteral nutrition solutions were supplied by the pharmacy with which we collaborated. To simulate the infusion conditions, the solutions were held in a patient room with standard lighting and temperature for 24 hours. Samples were taken at the beginning (group A) and the end (24th hour, group B) of the infusion period. The degradation products were 3-deoxyglucosone, pentosidine, N-carboxymethyl lysine, and 4-hydroxynonenal, which we investigated by high-performance liquid chromatography-mass spectrometry (LC-MS) and Q-TOF LC/MS methods. Two of four degradation products, 4-hydroxynonenal and N-carboxymethyl lysine, were detected in all samples, and Group B had higher levels of both compounds compared to Group A, who showed that the quantities of these compounds increased in room conditions over time. The increase was significant for 4-hydroxynonenal (p=0.03), but not for N-carboxymethyl lysine (p=0.23). Moreover, we detected in the parenteral nutrition solutions a compound that could have been 4-hydroxy-2-butynal or furanone.

Keywords:
Degradation products; Parenteral nutrition solution; Advanced glycation end-products; N-carboxymethyl lysine; 4-hydroxynonenal

INTRODUCTION

Infusion solutions must maintain stability from the start of the production process through to the transport, storage, and infusion stages. During the production process, irradiation and the heat generated may cause oxidation and lipid peroxidation (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.; Tovsen et al., 2015Tovsen ML, Smistad G, Bjerke TM, Tønnesen HH, Kristensen S. Physicochemical Stability of Emulsions and Admixtures for Parenteral Nutrition during Irradiation by Glass-Filtered Daylight at Standardized Conditions. PDA J Pharm Sci Technol . 2015;69(3):346-54.; Steger, Mühlebach, 1997Steger PJ, Mühlebach SF. In vitro oxidation of I.V. lipid emulsions in different all-in-one admixture bags assessed by an iodometric assay and gas-liquid chromatography. Nutrition. 1997;13(2):133-40.). Suboptimal handling conditions (e.g., temperature, daylight, long storage period) also affect stability (Hoff, Michaelson, 2009Hoff DS, Michaelson AS. Effects of light exposure on total parenteral nutrition and its implications in the neonatal population. J Pediatr Pharmacol Ther. 2009;14(3):132-43.; Turmezei et al., 2015Turmezei J, Jávorszky E, Szabó E, Dredán J, Kállai-Szabó B, Zelkó R. Effect of storage temperature on the stability of total parenteral nutrition admixtures prepared for infants. Acta Pol Pharm. 2015;72(5):843-9.; Thomovsky et al., 2008Thomovsky EJ, Backus RC, Mann FA, Richmond CK, Wagner-Mann CC. Effects of temperature and handling conditions on lipid emulsion stability in veterinary parenteral nutrition admixtures during simulated intravenous administration. Am J Vet Res. 2008;69(5):652-8.). Furthermore, the composition of the infusion solutions affects the stability of the product, especially in the parenteral nutrition solution (PNS) (Allwood, Kearney, 1998Allwood MC, Kearney MC. Compatibility and stability of additives in parenteral nutrition admixtures. Nutrition. 1998;14(9):697-706.; Jalabert et al., 2011Jalabert A, Grand A, Steghens JP, Barbotte E, Pigue C, Picaud JC. Lipid peroxidation in all-in-one admixtures for preterm neonates: impact of amount of lipid, type of lipid emulsion and delivery condition. Acta Paediatr. 2011;100(9):1200-05.). There must be (an) optimum ratio(s) and compatibility between the compounds in an infusion bag (Allwood, Kearney, 1998Allwood MC, Kearney MC. Compatibility and stability of additives in parenteral nutrition admixtures. Nutrition. 1998;14(9):697-706.; Jalabert et al., 2011Jalabert A, Grand A, Steghens JP, Barbotte E, Pigue C, Picaud JC. Lipid peroxidation in all-in-one admixtures for preterm neonates: impact of amount of lipid, type of lipid emulsion and delivery condition. Acta Paediatr. 2011;100(9):1200-05.). Such destabilizing factors cause degradation products that are toxic to the body to emerge in infusion solutions containing dextrose and peritoneal dialysis solutions (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.; Kawanishi et al., 2013Kawanishi K, Honda K, Tsukada M, Oda H, Nitta K. Neutral solution low in glucose degradation products is associated with less peritoneal fibrosis and vascular sclerosis in patients receiving peritoneal dialysis. Perit Dial Int . 2013;33(3):242-51.). These products are generally defined as glucose degradation products (GDPs), advanced glycation end-products (AGEs), and advanced lipoxidation end-products (ALEs), some of which are 3-deoxyglucosone (DG) and Nε-(1-Carboxymethyl)-L-lysine (CML) (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.; Kawanishi et al., 2013Kawanishi K, Honda K, Tsukada M, Oda H, Nitta K. Neutral solution low in glucose degradation products is associated with less peritoneal fibrosis and vascular sclerosis in patients receiving peritoneal dialysis. Perit Dial Int . 2013;33(3):242-51.).

Major sources of GDPs, AGEs, and ALEs are heat-processed foods and in vivo degradations (Poulsen et al., 2013Poulsen MW, Hedegaard RV, Andersen JM, de Courten B, Bügel S, Nielsen J, et al. Advanced glycation endproducts in food and their effects on health. Food Chem Toxicol. 2013;60:10-37.). However, infusional therapy in a patient is another source of a number of degradation products (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.). They have been identified in many cellular and systemic pathological processes of diabetes, atherosclerosis, chronic degenerative diseases, Alzheimer’s dementia, Parkinson’s disease, and cancer (Ajith, Vinodkumar, 2016Ajith TA, Vinodkumar P. Advanced glycation end products: Association with the pathogenesis of diseases and the current therapeutic advances. Curr Clin Pharmacol. 2016;11(2):118-27.). With regard to the acute effects of AGEs, AGEs potentiate the proinflammatory response, which results in ischemia/reperfusion injury and apoptosis (Watanabe et al., 2020Watanabe M, Toyomura T, Tomiyama M, Wake H, Liu K, Teshigawara K, et al. Advanced glycation end products (AGEs) synergistically potentiated the proinflammatory action of lipopolysaccharide (LPS) and high mobility group box-1 (HMGB1) through their direct interactions. Mol Biol Rep. 2020;47(9):7153-9.; Yang et al., 2019Yang J, Zhang F, Shi H, Gao Y, Dong Z, Ma L, et al. Neutrophil-derived advanced glycation end products-Nε-(carboxymethyl) lysine promotes RIP3-mediated myocardial necroptosis via RAGE and exacerbates myocardial ischemia/ reperfusion injury. FASEB J. 2019;33(12):14410-22.). GDPs impair neutrophil functions and anti-microbial efficacy by suppressing cytokine secretion according to the molecular variety of GDP (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.). A prospective study of critically ill patients reported a positive correlation between serum CML levels and elevated bilirubin levels and a negative correlation with serum CRP levels. Fortunately, no correlation was found between serum CML levels and the mortality of critically ill patients (Meertens et al., 2016Meertens JH, Nienhuis HL, Lefrandt JD, Schalkwijk CG, Nyyssönen K, Ligtenberg JJ, et al. The course of skin and serum biomarkers of advanced glycation endproducts and its association with oxidative stress, inflammation, disease severity, and mortality during ICU admission in critically ill patients: results from a prospective pilot study. PLoS One. 2016;11(8):e0160893.).

4-Hydroxynonenal (HNE) is a lipid peroxidation product (ALEs) and is present in blood circulation and tissues in various concentrations. It has proapoptotic and apoptotic effects and enhances oxidative stress (Shoeb et al., 2014Shoeb M, Ansari NH, Srivastava SK, Ramana KV. 4-Hydroxynonenal in the pathogenesis and progression of human diseases. Curr Med Chem. 2014;21(2):230-7.; Timucin, Basaga, 2017Timucin AC, Basaga H. Pro-apoptotic effects of lipid oxidation products: HNE at the crossroads of NF-κB pathway and anti-apoptotic Bcl-2. Free RadicBiol Med. 2017;111:209-18.). Its effect appears to be concentration-related because at low concentrations it induces cell proliferation, while at higher concentrations it causes cell death or a precancerous state and cancer (Guéraud, 2017Guéraud F. 4-Hydroxynonenal metabolites and adducts in pre-carcinogenic conditions and cancer. Free Radic Biol Med. 2017;111:196-208.; Yang et al., 2003Yang Y, Sharma A, Sharma R, Patrick B, Singhal SS, Zimniak P, et al. Cells preconditioned with mild, transient UVA irradiation acquire resistance to oxidative stress and UVA-induced apoptosis: role of 4-hydroxynonenal in UVA-mediated signaling for apoptosis. J Biol Chem. 2003;278(42):41380-8.).

High levels of AGEs and ALEs are probably more life-threatening in patients with acute diseases than in those with chronic ones. Therefore, limiting the accumulation of AGEs and ALEs in acute care patients (e.g., patients with sepsis) seems to be important (Christaki, Lazaridis, Opal, 2012Christaki E, Lazaridis N, Opal SM. Receptor for advanced glycation end products in bacterial infection: is there a role for immune modulation of receptor for advanced glycation end products in the treatment of sepsis? Curr Opin Infect Dis. 2012;25(3):304-11.). However, few studies report that low GDP levels in solutions or low AGE levels in circulation lead to less inflammation (Kawanishi et al., 2013Kawanishi K, Honda K, Tsukada M, Oda H, Nitta K. Neutral solution low in glucose degradation products is associated with less peritoneal fibrosis and vascular sclerosis in patients receiving peritoneal dialysis. Perit Dial Int . 2013;33(3):242-51.; Christaki, Lazaridis, Opal, 2012Christaki E, Lazaridis N, Opal SM. Receptor for advanced glycation end products in bacterial infection: is there a role for immune modulation of receptor for advanced glycation end products in the treatment of sepsis? Curr Opin Infect Dis. 2012;25(3):304-11.; Choi et al., 2008Choi HY, Kim DK, Lee TH, Moon SJ, Han SH, Lee JE, et al. The clinical usefulness of peritoneal dialysis fluids with neutral pH and low glucose degradation product concentration: an open randomized prospective trial. Perit Dial Int. 2008;28(2):174-82.).

Considering the above, we thought that PNS, which is composed of dextrose, lipids, and amino acids, may also contain a large number of GDPs, AGEs, and ALEs. To our knowledge, there is only one report on the presence of HNE in PNS (Schröter et al., 2021Schröter A, Mahler HC, Sayed NB, Koulov AV, Huwyler J, Jahn M. 4-Hydroxynonenal - A toxic leachable from clinically used administration materials. J Pharm Sci. 2021;110(9):3268-75.). However, no publication has been found about AGEs or ALEs in PNS and whether infusion conditions affect the quantities of AGEs or ALEs. We have, therefore, investigated these two issues in this study and the results reported in this study are the first of their kind in the literature.

MATERIAL AND METHODS

We supplied nine PNS packages from the hospital pharmacy store. The solutions were held in a patient wardroom under room conditions with standard ambient lighting for a total of 24 hours. The administration line was connected to an infusion pump, and the PNS was set to flow at 1.0 ml/min. Infusion conditions were simulated. The PNSs were emptied from each bag via IV fluid administration lines to mimic the administration to the patients. Samples were taken in glass bottles at the beginning (Group A) and at the end (24th hour - Group B) of the infusion period. Then, the samples were stored at -20°C until analysis.

The PNS bags were three-chambered and transparent and contained a total volume of 1540 ml of dextrose (150 gram-gr), lipids (60 gr), and amino acids (51 gr) for central infusion (Kabiven, Fresenius Kabi, Uppsala, Sweden). Each component was located in a separate chamber. The seals between the chambers were broken to mix the components before infusion.

The AGEs and ALEs investigated in PNS were DG, pentosidine, CML, and HNE (Figure 1). The degradation products analyzed were DG for dextrose, HNE for lipid, pentosidine and CML for amino acids and lipids, as described in the Maillard reaction (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.; Henning, Glomb, 2016Henning C, Glomb MA. Pathways of the Maillard reaction under physiological conditions. Glycoconj J. 2016;33(4):499-512.). Reference standards of DG (CAS 4084-27-9), CML (CAS 5746-04-3), and HNE (CAS 75899-68-2) were supplied from Santa Cruz Biotechnology Inc. (Texas, U.S.A.) and the reference standard of pentosidine (CAS 124505-87-9) was supplied from Cayman Chemical (Michigan, U.S.A.).

FIGURE 1
Molecular characteristics of the degradation products investigated

We used liquid chromatography-mass spectrometry (LC-MS/MS) (Shimadzu Nexera, Tokyo, Japan) and Quadrupole time-of-flight liquid chromatography-mass spectrometry (Q-TOF LC/MS) (Agilent 6530, CA, U.S.A.) methods to identify the degradation products in the matrix. Chromatographic techniques were performed in two parts: targeted analyses for pentosidine, DG, CML, and HNE in the LC-MS/MS analyzer and untargeted analyses for any unknown compound in the Q-TOF LC/ MS analyzer.

Preparation of Reference Standard for Targeted Degradation Products - AGEs

Reference standards of pentosidine, CML, and HNE were dissolved in a 50: 50% v/v methanol: water mixture and DG was dissolved in methanol by adding the solvent into the original flacons. We obtained 1000 parts per million (ppm), 1000 ppm, 10,000 ppm, and 1000 ppm solutions, respectively. These solutions were diluted between 0.1 and 1 ppm (0.1, 0.2, 0.4, 0.6, 1.0 ppm) with the mobile phase before being injected into the LC-MS/MS analyzer. A Merck SeQuant ZIC-HILIC (150x4.6 mm, 5 µm) column was used in a gradient elution mode (starting with 60% organic phase and ending with 10% at the 32nd minute) using water: acetonitrile, both including 0.1% formic acid.

Preparation of the PNS Samples

The samples were centrifuged at 14,000 rpm for 40 minutes at 20°C using an ultrafiltration tube (Amicon Ultra, 0.5 mL < 3 kDa) in a volume of 500 μL. After centrifugation, molecules less than 3 kDa in weight were collected by filtration. The collected solutions were diluted with the appropriate mobile phase for the targeted degradation products before being injected into the LC-MS/MS analyzer.

Analyses of Untargeted Degradation Products.

The samples were analyzed using a Waters XSelect HSS C18 (4.6 mm X 100 mm, 3.5 µm) column in a gradient elution mode (starting with 10% organic phase and ending with 90% at the 25th minute) using water: acetonitrile, both including 0.1% formic acid. Ultrafiltrates were diluted with 50% acetonitrile. The XCMS software program was used in LC-MS-based metabolomics analysis to detect and identify metabolites and assess differences between metabolite masses (Smith et al., 2006Smith CA, Want EJ, O’Maille G, Abagyan R, Siuzdak G. XCMS: processing mass spectrometry data for metabolite profiling using nonlinear peak alignment, matching, and identification. Anal Chem. 2006;78(3):779-87.). We used this program to process chromatograms from the Q-TOF LC/MS analyzer. In our study, compounds detected with quantities varying by ≥ 1.2 times between the two groups were considered to have statistical significance (Mihaleva et al., 2008Mihaleva VV, Vorst O, Maliepaard C, Verhoeven HA, de Vos RCH, Hall RD, et al. Accurate mass error correction in liquid chromatography time-of-flight mass spectrometry-based metabolomics. Metabolomics. 2008;4(2):171-82.).

Statistical Analysis

The data obtained for the two groups were compared using the paired T-test. Statistically, p < 0.05 was considered significant.

RESULTS AND DISCUSSION

The positive ionization mode peaks of pentosidine, DG, CML, and HNE were identified in the standard solutions at a 1 ppm concentration.

Detected Targeted Degradation Products

DG and pentosidine were not detected in the PNS samples of either group. However, the samples of both groups were found to contain two degradation products: CML and HNE. The mean peak values of CML and HNE were different between the two groups (Figures 2 and 3). A comparison of the quantities of CML and HNE in the PNS samples is presented in Table I. The difference was not statistically significant for CML (p=0.23) but was significant for HNE (p=0.03).

FIGURE 2
Chromatogram of N-Carboxymethyl lysine in the PNS shows a peak at 8.0 minutes.

FIGURE 3
Chromatogram of 4-Hydroxynonenal in the PNS shows a peak at 17.6 minutes.

TABLE I
CML and HNE levels (as µM) in groups and comparisons of means. SD: Standard deviation. P-value < 0.05 is considered to be significant

Detected Untargeted Degradation Products

An injection of the sample to show the base peak chromatogram (BPC) is given in Figure 4. Profiles were determined based on the mass of each compound that remained in the ultrafiltration. Twenty-five compounds were profiled, the majority of which were amino acids, and 2 compounds were found to have an increase of ≥ 1.2-fold between groups A and B (Figure 4, Table II). A METLIN data bank search regarding the mass-to-charge ratio (m/z) values showed that one of the compounds was a type of phthalate (Figure 5). The second compound was 4-hydroxy-2-butynal (4-HB), a different degradation product, or 2(3H)-furanone with the same m/z value. (Figure 6). We did not perform a further investigation on this compound.

FIGURE 4
A sample BPC of our analysis to show the untargeted analysis.

TABLE II
The characteristics of a type of phthalate and 4-Hydroxy-2-butynal (or furanone). *Mass spectroscopy indicates that the compounds are not mass but mass/charge (m/z)

FIGURE 5
Extracted ion chromatogram of phthalates in the PNS shows two different peaks between 1850 and 1900 seconds.

FIGURE 6
Extracted ion chromatogram of 4-Hydroxy-2-butynal or 2(3H)-Furanone in the PNS shows two different peaks between 100 and 140 seconds.

First of all, we should note that there is only one recently published report that is similar to our study. As a result, we have had to discuss our results in an indirect manner. The stability of compounds in PNS may be impaired during the manufacturing process, under suboptimal conditions of transport, storage, or infusion. The compatibility of the solution with the bag and drugs added to the bag may also affect the stability of the PNS. It has been reported that UVA irradiation and the heat generated during the manufacturing process may cause oxidation and lipid peroxidation (Bryland et al., 2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.; Tovsen et al., 2015Tovsen ML, Smistad G, Bjerke TM, Tønnesen HH, Kristensen S. Physicochemical Stability of Emulsions and Admixtures for Parenteral Nutrition during Irradiation by Glass-Filtered Daylight at Standardized Conditions. PDA J Pharm Sci Technol . 2015;69(3):346-54.; Steger, Mühlebach, 1997Steger PJ, Mühlebach SF. In vitro oxidation of I.V. lipid emulsions in different all-in-one admixture bags assessed by an iodometric assay and gas-liquid chromatography. Nutrition. 1997;13(2):133-40.). The pH of the PNS is lowered slightly by degradation secondary to UVA irradiation but significantly by concomitant lipid peroxidation (Tovsen et al., 2015Tovsen ML, Smistad G, Bjerke TM, Tønnesen HH, Kristensen S. Physicochemical Stability of Emulsions and Admixtures for Parenteral Nutrition during Irradiation by Glass-Filtered Daylight at Standardized Conditions. PDA J Pharm Sci Technol . 2015;69(3):346-54.; Steger, Mühlebach, 1997Steger PJ, Mühlebach SF. In vitro oxidation of I.V. lipid emulsions in different all-in-one admixture bags assessed by an iodometric assay and gas-liquid chromatography. Nutrition. 1997;13(2):133-40.). Fortunately, there are substances with antioxidant features, such as vitamins and trace elements, that can protect the PNS from degradation (Tovsen et al., 2015Tovsen ML, Smistad G, Bjerke TM, Tønnesen HH, Kristensen S. Physicochemical Stability of Emulsions and Admixtures for Parenteral Nutrition during Irradiation by Glass-Filtered Daylight at Standardized Conditions. PDA J Pharm Sci Technol . 2015;69(3):346-54.; Hoff, Michaelson, 2009Hoff DS, Michaelson AS. Effects of light exposure on total parenteral nutrition and its implications in the neonatal population. J Pediatr Pharmacol Ther. 2009;14(3):132-43.). However, this protection is controversial in some studies (Jalabert et al., 2011Jalabert A, Grand A, Steghens JP, Barbotte E, Pigue C, Picaud JC. Lipid peroxidation in all-in-one admixtures for preterm neonates: impact of amount of lipid, type of lipid emulsion and delivery condition. Acta Paediatr. 2011;100(9):1200-05.).

Storage conditions (e.g., temperature, light exposure, or storage duration) also affect the kinetic stability of PNS (Hoff, Michaelson, 2009Hoff DS, Michaelson AS. Effects of light exposure on total parenteral nutrition and its implications in the neonatal population. J Pediatr Pharmacol Ther. 2009;14(3):132-43.; Turmezei et al., 2015Turmezei J, Jávorszky E, Szabó E, Dredán J, Kállai-Szabó B, Zelkó R. Effect of storage temperature on the stability of total parenteral nutrition admixtures prepared for infants. Acta Pol Pharm. 2015;72(5):843-9.; Thomovsky et al., 2008Thomovsky EJ, Backus RC, Mann FA, Richmond CK, Wagner-Mann CC. Effects of temperature and handling conditions on lipid emulsion stability in veterinary parenteral nutrition admixtures during simulated intravenous administration. Am J Vet Res. 2008;69(5):652-8.). The mean oil droplet particle size and the zeta potential of the lipid are reported to be best at 2-8°C storage temperature. The current stability of the PNS is maintained for up to ten days (Turmezei et al., 2015Turmezei J, Jávorszky E, Szabó E, Dredán J, Kállai-Szabó B, Zelkó R. Effect of storage temperature on the stability of total parenteral nutrition admixtures prepared for infants. Acta Pol Pharm. 2015;72(5):843-9.). However, in several studies it has been shown to be maintained at optimal stability for 3-4 days (Thomovsky et al., 2008Thomovsky EJ, Backus RC, Mann FA, Richmond CK, Wagner-Mann CC. Effects of temperature and handling conditions on lipid emulsion stability in veterinary parenteral nutrition admixtures during simulated intravenous administration. Am J Vet Res. 2008;69(5):652-8.; Jalabert et al., 2011Jalabert A, Grand A, Steghens JP, Barbotte E, Pigue C, Picaud JC. Lipid peroxidation in all-in-one admixtures for preterm neonates: impact of amount of lipid, type of lipid emulsion and delivery condition. Acta Paediatr. 2011;100(9):1200-05.). Vitamins may also be affected (or destabilized) by storage temperature (for example, ascorbic acid in the PNS may denature rapidly within 24 hours at 25°C or within 72 hours at 2-8°C) (Turmezei et al., 2015Turmezei J, Jávorszky E, Szabó E, Dredán J, Kállai-Szabó B, Zelkó R. Effect of storage temperature on the stability of total parenteral nutrition admixtures prepared for infants. Acta Pol Pharm. 2015;72(5):843-9.).

Plastic containers of the PNS are in the form of multilayer films and are generally composed of polypropylamine-polyamide or ethyl vinyl acetate. These containers have an affinity for lipid globules and interact especially with triglycerides. The interaction of lipids with plastic containers is more evident than with glass containers (Driscoll et al., 2007Driscoll DF, Silvestri AP, Bistrian BR, Mikrut BA. Stability of total nutrient admixtures with lipid injectable emulsions in glass versus plastic packaging. Am J Health Syst Pharm. 2007;64(4):396-403.; Gonyon et al., 2013Gonyon T, Tomaso AE Jr, Kotha P, Owen H, Patel D, Carter PW, et al. Interactions between parenteral lipid emulsions and container surfaces. PDA J Pharm Sci Technol. 2013;67(3):247-54.). In addition, peroxide formation in the PNS has been reported to be significant in plastic containers over time compared to in glass containers. The composition of the containers used also affects the pH of the PNS. It has been reported that the decrease of pH in PNS occurs more in polypropylamine-polyamide containers than in ethyl vinyl acetate containers (Steger, Mühlebach, 1997Steger PJ, Mühlebach SF. In vitro oxidation of I.V. lipid emulsions in different all-in-one admixture bags assessed by an iodometric assay and gas-liquid chromatography. Nutrition. 1997;13(2):133-40.). The chemical composition of the containers can also facilitate the release of compound dissolutions into the solutions (Schröter et al., 2021Schröter A, Mahler HC, Sayed NB, Koulov AV, Huwyler J, Jahn M. 4-Hydroxynonenal - A toxic leachable from clinically used administration materials. J Pharm Sci. 2021;110(9):3268-75.). We also found phthalate (without typing) in the PNS that lends support to the same suggestion.

PNS seems to be photosensitive. Peroxide formation in the PNS is increased if the container and infusion set are transparent and exposed to light or phototherapy. Hoff and colleagues (2009Hoff DS, Michaelson AS. Effects of light exposure on total parenteral nutrition and its implications in the neonatal population. J Pediatr Pharmacol Ther. 2009;14(3):132-43.) stated that the use of a colored infusion bag and infusion set prevented the photodegradation of PNS compounds and inhibited the formation of peroxide. If the PNS is stored under exposure to light for less than 72 hours, the state of the lipid emulsion will not change. However, if PNS is stored under exposure to light for more than 72 hours, light may increase peroxidation and may cause malondialdehyde formation (Jalabert et al., 2011Jalabert A, Grand A, Steghens JP, Barbotte E, Pigue C, Picaud JC. Lipid peroxidation in all-in-one admixtures for preterm neonates: impact of amount of lipid, type of lipid emulsion and delivery condition. Acta Paediatr. 2011;100(9):1200-05.). A colored or lightproof container is also recommended to protect vitamins (especially vitamins A and E, which degrade rapidly) from photodegradation (Allwood, Martin, 2000Allwood MC, Martin HJ. The photodegradation of vitamins A and E in parenteral nutrition mixtures during infusion. Clin Nutr. 2000;19(5):339-42.). However, the relationship between vitamins and PNS in terms of vitamin degradation and lipid peroxidation is a contentious issue (Jalabert et al., 2011Jalabert A, Grand A, Steghens JP, Barbotte E, Pigue C, Picaud JC. Lipid peroxidation in all-in-one admixtures for preterm neonates: impact of amount of lipid, type of lipid emulsion and delivery condition. Acta Paediatr. 2011;100(9):1200-05.).

Another factor affecting the stability of the PNS is the handling position. It is reported that lipids in the PNS remain stable for 48 hours at room temperature, and intermittent agitation does not affect the size of the lipid particles. However, continuous agitation of the PNS causes a visible oil layer in the container and administration set by the 72nd hour (Thomovsky et al., 2008Thomovsky EJ, Backus RC, Mann FA, Richmond CK, Wagner-Mann CC. Effects of temperature and handling conditions on lipid emulsion stability in veterinary parenteral nutrition admixtures during simulated intravenous administration. Am J Vet Res. 2008;69(5):652-8.).

We detected CML and HNE in the PNS among the investigated AGEs: DG, pentosidine, CML, and HNE. In addition, we determined that the amounts of CML and HNE increased from the beginning to the end of the infusion within 24 hours under room conditions, and that the increase of HNE was significant. Similar to our results, Bryland and colleagues (2010Bryland A, Broman M, Erixon M, Klarin B, Lindén T, Friberg H, et al. Infusion fluids contain harmful glucose degradation products. Intensive Care Med. 2010;36(7):1213-20.) reported GDPs were detected in glucose-containing infusion fluids, and serum CML levels in patients were found to increase significantly in time due to infusion. A recent study by Schröter and colleagues (2021Schröter A, Mahler HC, Sayed NB, Koulov AV, Huwyler J, Jahn M. 4-Hydroxynonenal - A toxic leachable from clinically used administration materials. J Pharm Sci. 2021;110(9):3268-75.) reported that there was HNE in saline solutions, indicating that it was a leachable compound released from polyvinyl chloride of the administration sets (container + line). Therefore, the origin of NHE may not be the PNS or may be the PNS and the container as well. This issue needs to be clarified in new studies.

In our study, we also determined two different compounds (a type of phthalate and 4-HB or furanone) in the PNS that increased over time. Phthalates are known to be toxic and are generally added to plastics to obtain flexibility. These compounds decompose from the plastic container of the PNS and mix into the solution. Phthalates have been detected in the plasma of infants and children (Kambia et al., 2013Kambia N, Dine T, Gressier B, Luyckx M, Brunet C, Guimber D, et al. Strong variability of di(2-ethylhexyl) phthalate (DEHP) plasmatic rate in infants and children undergoing 12-hour cyclic parenteral nutrition. JPEN J Parenter Enteral Nutr. 2013;37(2):229-35.). The second compound found in the PNS was 4-HB or furanone, with the same m/z values. The exact determination of this compound is beyond the scope of this study and needs further investigation.

Considering the above, there may be even more different degradation products in PNS. Therefore, it is considered that more applications to maintain the stability of the PNS from the beginning of the manufacturing process to the end of the infusion process (e.g., using light-proof, colored, or low-volume containers and using more stable compounds for production of less flexible containers) are required.

CONCLUSION

Two types of degradation products, CML and HNE, were detected in the PNS, and levels of both were found to be higher at the end of the infusion time under standard ambient lighting and room conditions, with a significant increase in the level of HNE. We also determined two different compounds (a type of phthalate and 4-HB or furanone) in the PNS that increased over time, suggesting that there may be further different degradation products in existence.

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ACKNOWLEDGEMENTS

  • Funding:

    A grant from the Abant İzzet Baysal University (Bolu - Türkiye) was supplied for the research part of this study [grant no: 140814.721].

Publication Dates

  • Publication in this collection
    28 Aug 2023
  • Date of issue
    2023

History

  • Received
    27 Jan 2023
  • Accepted
    04 June 2023
Universidade de São Paulo, Faculdade de Ciências Farmacêuticas Av. Prof. Lineu Prestes, n. 580, 05508-000 S. Paulo/SP Brasil, Tel.: (55 11) 3091-3824 - São Paulo - SP - Brazil
E-mail: bjps@usp.br