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MB Sample ID: SA220783
Local Sample ID: | F08_V4 |
Subject ID: | SU002383 |
Subject Type: | Human |
Subject Species: | Homo sapiens |
Taxonomy ID: | 9606 |
Select appropriate tab below to view additional metadata details:
Subject:
Subject ID: | SU002383 |
Subject Type: | Human |
Subject Species: | Homo sapiens |
Taxonomy ID: | 9606 |
Factors:
Local Sample ID | MB Sample ID | Factor Level ID | Level Value | Factor Name |
---|---|---|---|---|
F08_V4 | SA220783 | FL027476 | Treated | Treatedrial arm |
Collection:
Collection ID: | CO002376 |
Collection Summary: | Serum and urine samples were collected at the three study sites; Liverpool, Paris and Piešťany. Samples collected at Paris and Piešťany were transported frozen to the Royal Liverpool University Hospital for metabolite analysis and storage at -80 °C. Urine was collected over 24-h into 2.5 L bottles containing 30 mL of 5 mol/L sulphuric acid which was subsequently aliquoted and stored at -80 °C. |
Sample Type: | Urine |
Storage Conditions: | -80℃ |
Treatment:
Treatment ID: | TR002395 |
Treatment Summary: | Samples studied were from patients partaking in the SONIA 2 clinical trial of nitisinone in AKU. SONIA 2 was a 4-year, open-label, evaluator-blind, randomised, no treatment controlled, parallel-group study undertaken at three study sites; Liverpool (UK), Paris (France) and Piešťany (Slovakia). The details and outcomes of the trial are published (1). Serum and urine samples were collected from participants at baseline (pre-treatment) then at 3 months and 1, 2, 3 and 4 years on 10 mg oral daily nitisinone (Orfadin®) treatment or no treatment. The serum and urine samples from visit 1 (baseline; pre-treatment), visit 4 (2 years), visit 6 (4 years) underwent metabolomic analysis. In this study, only the data from patients with samples available for these three time points were included; 53 and 50 patients in treated and untreated groups respectively for urine, and 47 and 45 patients in treated and untreated groups respectively for serum. Reference: (1) Ranganath, L.R.; Psarelli, E.E.; Arnoux, J.B.; Braconi, D.; Briggs, M.; Bröijersén, A.; Loftus, N.; Bygott, H.; Cox, T.F.; Davison, A.S.; et al. Efficacy and Safety of Once-Daily Nitisinone for Patients with Alkaptonuria (SONIA 2): An International, Multicentre, Open-Label, Randomised Controlled Trial. Lancet Diabetes Endocrinol. 2020, 8, 762–772, doi:10.1016/S2213-8587(20)30228-X. |
Treatment Protocol ID: | Clinical trial ID: EudraCT no. 2013-001633-41 |
Treatment Compound: | Nitisinone (NTBC) |
Treatment Dose: | 10 mg daily |
Treatment Doseduration: | 48 months total |
Sample Preparation:
Sampleprep ID: | SP002389 |
Sampleprep Summary: | Prior to analysis, urine samples were thawed at room temperature before vortexing and centrifugation at 1500 ×g for 5 minutes. 150 µL of each urine sample was aliquoted into a 1 mL 96-well plate (Waters Corporation, Wilmslow, UK) and diluted with 450 µL of deionised water. Samples were mixed on a plate shaker (MTS 2/4m IKA) at 600 rpm for 10 min and sub-aliquoted into multiple replicate 96-well plates before storage at -80 °C ready for analysis. Prior to analysis, sample plates were thawed then agitated on a plate shaker (MTS 2/4m IKA) at 600 rpm for 10 min. |
Combined analysis:
Analysis ID | AN003752 | AN003753 |
---|---|---|
Analysis type | MS | MS |
Chromatography type | Reversed phase | Reversed phase |
Chromatography system | Agilent 1290 Infinity II | Agilent 1290 Infinity II |
Column | Waters Atlantis dC18 (100 x 3mm,3um) | Waters Atlantis dC18 (100 x 3mm,3um) |
MS Type | ESI | ESI |
MS instrument type | QTOF | QTOF |
MS instrument name | Agilent 6550 QTOF | Agilent 6550 QTOF |
Ion Mode | NEGATIVE | POSITIVE |
Units | peak area (pareto-scaled, log2-transformed, 24h creatinine normalised) | peak area (pareto-scaled, log2-transformed, 24h creatinine normalised) |
Chromatography:
Chromatography ID: | CH002777 |
Chromatography Summary: | Analysis of serum and urine samples was performed using a published LC-QTOF-MS acquisition method, which employed a 1290 Infinity II HPLC coupled to a 6550 QTOF-MS equipped with dual AJS electrospray ionisation source (Agilent, Cheadle, UK). Data acquisition parameters are detailed in brief below and in full in Supplementary Materials. Reversed-phase LC was performed on an Atlantis dC18 column (3×100 mm, 3 μm, Waters, Manchester, UK) maintained at 60 °C. Mobile phase composition was (A) water and (B) methanol, both with 5 mmol/L ammonium formate and 0.1 % formic acid. The elution gradient began at 5 % B 0–1 min and increased linearly to 100 % B by 12 min, held at 100 % B until 14 min, then at 5 % B for a further 5 min. MS data acquisition was performed in positive and negative ionisation polarity with mass range 50–1700 in 2 GHz mode with acquisition rate at 3 spectra/second. Sample injection volume was 1 and 2 µL in negative and positive polarities, respectively. |
Instrument Name: | Agilent 1290 Infinity II |
Column Name: | Waters Atlantis dC18 (100 x 3mm,3um) |
Column Temperature: | 60 |
Flow Gradient: | The elution gradient began at 5 % B 0–1 min and increased linearly to 100 % B by 12 min, held at 100 % B until 14 min, then at 5 % B for a further 5 min. |
Solvent A: | 100% water; 0.1% formic acid; 5mM ammonium formate |
Solvent B: | 100% methanol; 0.1% formic acid; 5mM ammonium formate |
Chromatography Type: | Reversed phase |
MS:
MS ID: | MS003496 |
Analysis ID: | AN003752 |
Instrument Name: | Agilent 6550 QTOF |
Instrument Type: | QTOF |
MS Type: | ESI |
MS Comments: | MS acquisition conditions detailed in attached Supplementary Materials. Raw data were mined using the targeted feature extraction function in Masshunter Profinder (build 10.00, Agilent) with mass targets based on chemical formulae of known/predicted phe-tyr pathway metabolites from the customised compound databases described below. A combined compound database was compiled using PCDL Manager (Agilent, build 08.00). Accurate mass retention time (AMRT) matched metabolites were present in our published AMRT database, which was generated from chemical standards using the same LC-QTOF-MS methodology employed here: phenylalanine, phenylethylamine, tyrosine, N-acetyl-tyrosine, tyramine, HPPA, HPLA and HGA. Other established phenylalanine metabolites added to the database for mining by accurate mass alone were hydroxyphenylacetic acid, phenylacetaldehyde, phenylacetamide, phenylacetic acid, phenylacetylglutamine, phenylethylamine, phenyllactic acid and phenylpyruvic acid. The remaining formulae were from non-established but theoretically possible phase 1 and 2 biotransformation products derived from phenylalanine (n=74), tyrosine (n=74), HPPA (n=67) and HPLA (n=67) predicted using the Biotransformation Mass Defects tool (Agilent), in addition to the HGA biotransformation products (n=7) previously established by our group. Feature extraction parameters were accurate mass match window ±5 ppm with addition of matched retention time (RT; window ±0.3 min) for AMRT database metabolites. Allowed ion species were: H+, Na+, and NH4+ in positive polarity, and H− and CHO2- in negative polarity. Charge state range was 1–2, and dimers were allowed. ‘Find by formula’ filters were: score >60 in at least 60 % of samples in at least one sample group. Where compounds were detected in both positive and negative ionisation, the polarity with the clearest signal was selected for further analysis. Extracted peak area intensity data were exported in .csv file format and imported into Mass Profiler Professional (MPP; build 15.1, Agilent), in which all statistical analyses were performed unless stated otherwise. In MPP, all data were log2 transformed and pareto scaled. Urine data were normalised to 24-h creatinine values. QC was performed based on compound signal intensity data from the pooled samples interspersed throughout each analytical sequence. Compounds were retained for subsequent statistical analyses if a) observed in 100 % of replicate injections for at least one sample group pool, and b) peak area coefficient of variation (CV) remained <30% across replicate injections for each sample group pool across batches 1 and 2 combined. |
Ion Mode: | NEGATIVE |
MS ID: | MS003497 |
Analysis ID: | AN003753 |
Instrument Name: | Agilent 6550 QTOF |
Instrument Type: | QTOF |
MS Type: | ESI |
MS Comments: | MS acquisition conditions detailed in attached Supplementary Materials. Raw data were mined using the targeted feature extraction function in Masshunter Profinder (build 10.00, Agilent) with mass targets based on chemical formulae of known/predicted phe-tyr pathway metabolites from the customised compound databases described below. A combined compound database was compiled using PCDL Manager (Agilent, build 08.00). Accurate mass retention time (AMRT) matched metabolites were present in our published AMRT database, which was generated from chemical standards using the same LC-QTOF-MS methodology employed here: phenylalanine, phenylethylamine, tyrosine, N-acetyl-tyrosine, tyramine, HPPA, HPLA and HGA. Other established phenylalanine metabolites added to the database for mining by accurate mass alone were hydroxyphenylacetic acid, phenylacetaldehyde, phenylacetamide, phenylacetic acid, phenylacetylglutamine, phenylethylamine, phenyllactic acid and phenylpyruvic acid. The remaining formulae were from non-established but theoretically possible phase 1 and 2 biotransformation products derived from phenylalanine (n=74), tyrosine (n=74), HPPA (n=67) and HPLA (n=67) predicted using the Biotransformation Mass Defects tool (Agilent), in addition to the HGA biotransformation products (n=7) previously established by our group. Feature extraction parameters were accurate mass match window ±5 ppm with addition of matched retention time (RT; window ±0.3 min) for AMRT database metabolites. Allowed ion species were: H+, Na+, and NH4+ in positive polarity, and H− and CHO2- in negative polarity. Charge state range was 1–2, and dimers were allowed. ‘Find by formula’ filters were: score >60 in at least 60 % of samples in at least one sample group. Where compounds were detected in both positive and negative ionisation, the polarity with the clearest signal was selected for further analysis. Extracted peak area intensity data were exported in .csv file format and imported into Mass Profiler Professional (MPP; build 15.1, Agilent), in which all statistical analyses were performed unless stated otherwise. In MPP, all data were log2 transformed and pareto scaled. Urine data were normalised to 24-h creatinine values. QC was performed based on compound signal intensity data from the pooled samples interspersed throughout each analytical sequence. Compounds were retained for subsequent statistical analyses if a) observed in 100 % of replicate injections for at least one sample group pool, and b) peak area coefficient of variation (CV) remained <30% across replicate injections for each sample group pool across batches 1 and 2 combined. |
Ion Mode: | POSITIVE |