Physicochemical stability of high-concentration cefuroxime aqueous injection reconstituted by a centralised intravenous additive service.

OBJECTIVES: Hospital pharmacies provide centralised intravenous additive services (CIVAS), such as antibiotic reconstitution. The aim of this study was to demonstrate the physicochemical stability of high-concentration cefuroxime sodium in aqueous injections, which is mandatory for the centralised preparation of products with automation. METHODS: The physicochemical stability of three high-concentration injections (1.5 g of cefuroxime sodium in 15 mL, 16 mL and 18 mL of water for injection (WFI)) were studied in two primary packing materials (glass vials and polypropylene syringes). The samples were reconstituted with automation in three mid-sized hospital pharmacies in a good manufacturing practice (GMP) grade A/B cleanroom. During the study, the samples were stored in refrigerated conditions (4°C) and 1.5 g/15 mL solution in ambient temperature (22°C). Cefuroxime and descarbamoyl cefuroxime were analysed by high-performance liquid chromatography with UV detection. In addition, the appearance, pH and uniformity of dosage units were investigated. RESULTS: The freshly prepared cefuroxime injections fulfilled the criteria of content uniformity (acceptance value (AV) <15). A significant decrease in concentration of cefuroxime and increase in content of descarbamoyl cefuroxime was observed in all injections. Cefuroxime aqueous injections were physiochemically stable for up to 14 days under refrigeration storage. The relative content of descarbamoyl cefuroxime remained under 3% at 4°C. The solution of 1.5 g/15 mL was stable for only 20 hours in formulations stored for the first 14 days at 4°C and then transferred to 22°C. The colour of the solution changed from light yellow to a darker yellow, and the pH value of the solutions increased during storage. Neither primary packing materials, commercial source of cefuroxime sodium nor exposure to light had any significant effect on the stability of formulations. CONCLUSIONS: Although limited, we found the shelf life of high-concentration cefuroxime injections in refrigerated conditions sufficient for centralised antibiotic preparation in hospital pharmacy with automation. The limited shelf life of high-concentration cefuroxime injections must be considered when using these formulations.

Comparative steroid profiling of newborn hair and umbilical cord serum highlights the role of fetal adrenals, placenta, and pregnancy outcomes in fetal steroid metabolism.

Previous steroid hormone studies concerning pregnancy and newborns have mainly focused on glucocorticoids; wider steroid profiles have been less commonly investigated. Here, we performed a comparative analysis of 17 steroids from newborn hair and umbilical cord serum at the time of delivery. The study participants (n = 42, 50% girls) were a part of the Kuopio Birth Cohort and represent usual Finnish pregnancies. The hair and cord serum samples were analyzed with liquid chromatography high resolution mass spectrometry and triple quadrupole tandem mass spectrometry, respectively. We detected high individual variations in steroid hormone concentrations in both sample matrices. The concentrations of cortisol (F), corticosterone (B), estrone (E1), estradiol (E2), dehydroepiandrosterone (DHEA), 11ß-hydroxyandostenedione (11bOHA4), 5α-androstanedione (DHA4), and 17α-hydroxypregnenolone (17OHP5) correlated positively between cord serum and newborn hair samples. In addition, F and 11bOHA4 concentrations correlated positively with each other in both newborn hair and cord serum samples. The cortisone-to-cortisol ratio (E/F) was significantly higher in cord serum than in newborn hair samples reflecting high placental 11ßHSD2 enzyme activity. Only minor sex differences in steroid concentrations were observed; higher testosterone (T) and 11-deoxycortisol (S) with lower 11bOHA4 in male cord serum, and higher DHEA, androstenedione (A4) and 11bOHA4 in female newborn hair samples. Parity and delivery mode were the most significant pregnancy- and birth-related parameters associating with F and some other adrenocortical steroid concentrations. This study provides novel information about intrauterine steroid metabolism in late pregnancy and typical concentration ranges for several newborn hair steroids, including also 11-oxygenated androgens.

An integrative analysis of endometrial steroid metabolism and transcriptome in relation to endometrial receptivity in in vitro fertilization patients.

OBJECTIVE: To study the relationship between the steroid concentration in the endometrium, in serum, and the gene expression level of steroid-metabolizing enzymes in the context of endometrial receptivity in in vitro fertilization (IVF) patients. DESIGN: Case-control study of 40 IVF patients recruited in the SCRaTCH study (NTR5342), a randomized controlled trial investigating pregnancy outcome after "endometrial scratching." Endometrial biopsies and serum were obtained from patients with a first failed IVF cycle randomized to the endometrial scratch in the midluteal phase of the natural cycle before the next fresh embryo transfer during the second IVF cycle. SETTING: University hopsital. PATIENTS: Twenty women with clinical pregnancy were compared with 20 women who did not conceive after fresh embryo transfer. Cases and controls were matched for primary vs. secondary infertility, embryo quality, and age. INTERVENTION: None. MAIN OUTCOME MEASURE(S): Steroid concentrations in endometrial tissue homogenates and serum were measured with liquid chromatography-mass spectrometry. The endometrial transcriptome was profiled by RNA-sequencing, followed by principal component analysis and differential expression analysis. False discovery rate-adjusted and log-fold change >|0.5| were selected as the threshold for differentially expressed genes. RESULT(S): Estrogen levels were comparable in both serum (n = 16) and endometrium (n = 40). Androgens and 17-hydroxyprogesterone were higher in serum than that in endometrium. Although steroid levels did not vary between pregnant and nonpregnant groups, subgroup analysis of primary women with infertility showed a significantly lower estrone concentration and estrone:androstenedione ratio in serum of the pregnant group (n = 5) compared with the nonpregnant group (n = 2). Expression of 34 out of 46 genes encoding the enzymes controlling the local steroid metabolism was detected, and estrogen receptor ß gene was differentially expressed between pregnant and nonpregnant women. When only the primary infertile group was considered, 28 genes were differentially expressed between pregnant and nonpregnant women, including HSD11B2, that catalyzes the conversion of cortisol into cortisone. CONCLUSION(S): Steroidomic and transcriptomic analyses show that steroid concentrations are regulated by the local metabolism in the endometrium. Although no differences were found in endometrial steroid concentration in the pregnant and nonpregnant IVF patients, primary women with infertility showed deviations in steroid levels and gene expression, indicating that a more homogeneous patient group is required to uncover the exact role of steroid metabolism in endometrial receptivity. CLINICAL TRIAL REGISTRATION NUMBER: The study was registered in the Dutch trial registry (www.trialregister.nl), registration number NL5193/NTR5342, available at https://trialsearch.who.int/Trial2.aspx?TrialID=NTR6687. The date of registration is July 31, 2015. The first enrollment is on January 1, 2016.

A quantitative ultra-performance liquid chromatography high-resolution mass spectrometry analysis of steroids from human scalp hair.

Hair steroid analysis offers the possibility to evaluate long-term steroid metabolism. It is especially beneficial when studying the steroid milieu in newborns and children, for example it can provide new insights into steroid metabolism over months and is unaffected by diurnal fluctuations in steroid concentrations. This study describes a quantitative and highly selective high-resolution mass spectrometry method for the simultaneous analysis of multiple steroids from human scalp hair. The developed method utilizes parallel reaction monitoring in the analysis of hydroxylamine derivatized steroids from hair samples first washed with isopropanol, extracted with methanol, and further purified with solid-phase extraction and liquid-liquid extraction. The method was proven suitable for the quantitative analysis of endogenous glucocorticoids (cortisol [1.5-364 pg/mg]; cortisone [3.6-355 pg/mg]; corticosterone [0.7-347 pg/mg]; 11-deoxycortisol [0.1-343 pg/mg]), androgens (testosterone [0.1-288 pg/mg]; dehydroepiandrosterone [0.3-288 pg/mg]; androstenedione [0.1-285 pg/mg]; 11ß-hydroxyandrostenedione [0.3-304 pg/mg]), progestogens (pregnenolone [0.1-313 pg/mg]; progesterone [0.1-313 pg/mg]; 17α-hydroxypregnenolone [0.3-315 pg/mg]; 17α-hydroxyprogesterone [0.7-330 pg/mg]; 21-hydroxyprogesterone [0.6-320 pg/mg]), and estrogens (estrone [0.1-267 pg/mg]; estradiol [0.5-274 pg/mg]). In addition, 11-ketoandrostenedione [0.6-60 pg/mg]; dihydrotestosterone [0.3-290 pg/mg]; 11-ketotestosterone [0.1-12 pg/mg]; and 5α-androstanedione [0.6-281 pg/mg] could be analyzed semi-quantitatively. Aldosterone [3.5-346 pg/mg]; 11ß-hydroxytestosterone [0.3-300 pg/mg]; and 11-ketodihydrotestosterone [0.3-300 pg/mg] were also included in the method, but their concentrations were below the lower limit of quantification in all tested hair samples. The method was applied for the analysis of authentic hair samples from different age groups ranging from newborns to adults, including mothers within 48 h after delivery. The newborn hair samples displayed the widest variety and had also the highest amounts of steroids in comparison to the samples of the other groups.

Serum Creatine, Not Neurofilament Light, Is Elevated in CHCHD10-Linked Spinal Muscular Atrophy.

OBJECTIVE: To characterize serum biomarkers in mitochondrial CHCHD10-linked spinal muscular atrophy Jokela (SMAJ) type for disease monitoring and for the understanding of pathogenic mechanisms. METHODS: We collected serum samples from a cohort of 49 patients with SMAJ, all carriers of the heterozygous c.197G>T p.G66V variant in CHCHD10. As controls, we used age- and sex-matched serum samples obtained from Helsinki Biobank. Creatine kinase and creatinine were measured by standard methods. Neurofilament light (NfL) and glial fibrillary acidic protein (GFAP) were measured with single molecule array (Simoa), fibroblast growth factor 21 (FGF-21), and growth differentiation factor 15 (GDF-15) with an enzyme-linked immunosorbent assay. For non-targeted plasma metabolite profiling, samples were analyzed with liquid chromatography high-resolution mass spectrometry. Disease severity was evaluated retrospectively by calculating a symptom-based score. RESULTS: Axon degeneration marker, NfL, was unexpectedly not altered in the serum of patients with SMAJ, whereas astrocytic activation marker, GFAP, was slightly decreased. Creatine kinase was elevated in most patients, particularly men. We identified six metabolites that were significantly altered in serum of patients with SMAJ in comparison to controls: increased creatine and pyruvate, and decreased creatinine, taurine, N-acetyl-carnosine, and succinate. Creatine correlated with disease severity. Altered pyruvate and succinate indicated a metabolic response to mitochondrial dysfunction; however, lactate or mitochondrial myopathy markers FGF-21 or GDF-15 was not changed. CONCLUSIONS: Biomarkers of muscle mass and damage are altered in SMAJ serum, indicating a role for skeletal muscle in disease pathogenesis in addition to neurogenic damage. Despite the minimal mitochondrial pathology in skeletal muscle, signs of a metabolic shift can be detected.

Simultaneous analysis by LC-MS/MS of 22 ketosteroids with hydroxylamine derivatization and underivatized estradiol from human plasma, serum and prostate tissue.

This study describes a validated LC-MS/MS method for assaying 23 steroids within a single run from 150 µl of human plasma, serum or prostatic tissue homogenate. Isotope-labeled steroids were used as internal standards. Samples were extracted with toluene, and ketosteroids were derivatized with hydroxylamine prior to LC-MS/MS analysis. The steroids were separated on a C18 column and methanol was used as an organic solvent with the addition of 0.2 mM ammonium fluoride to improve underivatized estradiol (E2) ionization. Certified reference serums as well as plasma samples, and homogenates of prostate tissue were utilized in the method validation. The specificity of the method was inspected with a total of 27 steroids. The validation proved that the method was suitable for the quantitative analysis of a wide panel of androgens (testosterone, T (3.3 pM-13 nM); androstenedione, A4 (3.3 pM-13 nM); 5α-androstanedione, DHA4 (13 pM-13 nM); dehydroepiandrosterone, DHEA (67 pM-133 nM); dihydrotestosterone, DHT (33 pM-33 nM); 11-ketodihydrotestosterone, 11KDHT (13 pM-13nM); 11-ketotestosterone, 11KT (33 pM-6.7 nM); 11ß-hydroxyandrostenedione, 11bOHA4 (33 pM-13 nM); 11ß-hydroxytestosterone, 11OHT (13 pM-33 nM)), as well as estrogens (estrone, E1 (3.3 pM-13 nM)), progestagens (17α-hydroxypregnenolone, 17OHP5 (32 pM-127 nM); 17α-hydroxyprogesterone, 17OHP4 (67 pM-133 nM); progesterone, P4 (3.3 pM-13 nM); pregnenolone, P5 (6.6 pM-13 nM)), and glucocorticoids (cortisol, F (33 pM-134 nM); cortisone E (66 pM-131 nM); corticosterone, B (33 pM-67 nM); 11-deoxycortisol, S (33 pM-66 nM); 21-hydroxyprogesterone, 21OHP4 (32 pM-13 nM)). Furthermore, E2 (335 pM-134 nM) and 11α-hydroxyandrostenedione, 11aOHA4 (33 pM-33 nM) could be analyzed if the concentration in the sample was high enough. In addition, aldosterone, A (128 pM-64 nM) and 11-ketoandrostenedione, 11KA4 (33 pM-13 nM) could be analyzed semiquantitatively. The limits of quantification for all compounds ranged from 0.9 to 91 pg/ml, and from 0.009 to 0.9 pg/mg tissue. Compared to our previous method, this new method also permits the analysis of the more challenging steroids, like DHT, DHEA and P5, and a panel of 11-ketosteroids.