Development of a competitive binding homogeneous mobility shift assay for the quantification of adalimumab levels in patient serum.

Adalimumab is a TNF specific monoclonal widely used therapeutically. Monitoring adalimumab levels is important for guiding treatment strategies and is predominantly performed using an ELISA. The homogeneous mobility shift assay (HMSA) has many advantages over an ELISA for adalimumab monitoring but current HMSA methodologies do not discriminate between adalimumab and other TNF specific monoclonals such as infliximab. The development and validation of a competitive binding HMSA (cHMSA) specific for adalimumab is reported here. The cHMSA had a lower limit of quantitation of 1.25 µg/ml and the intra-assay and inter-assay coefficents of variation (CV) were <20%. No signal was detected in adalimumab naïve control serum including those containing rheumatoid factor or infliximab. The majority (14/20) of adalimumab patient samples containing anti-adalimumab antibodies gave a cHMSA signal >3 standard deviations lower than the controls. The performance of the cHMSA and an ELISA was compared using adalimumab patient samples (n = 82). There was a strong correlation between the assays (r = 0.91) and the intra-class correlation coefficient (0.88) was indicative of good-excellent inter-assay reliability. Bland-Altman plots showed little overall bias and comparison of the sub-groups defined using cut-points (1.25 or 7.3 µg/ml) gave percent agreement (>90%) and Cohens kappa (95% CI: 0.61-0.93) values indicative of substantial-almost perfect agreement. These results demonstrate that cHMSA provides an accurate and specific method for monitoring adalimumab levels and can additionally provide an initial screen for the presence of anti-adalimumab antibodies.

Discrimination of Anti-drug Antibodies With Neutralizing Capacity in Infliximab- and Adalimumab-Treated Patients: Comparison of the Homogeneous Mobility Shift Assay and the Affinity Capture and Elution Assay.

BACKGROUND: The measurement of anti-drug antibody (ADA) levels in adalimumab (ADAL)-treated and infliximab (IFX)-treated patients is critical for guiding therapeutic strategies. The homogeneous mobility shift assay (HMSA) and affinity capture elution (ACE) assay provide effective, drug-tolerant formats for measuring total ADA levels. However, their ability to discriminate between ADA from samples with or without neutralizing capacity is unclear and therefore was analyzed in this study. METHODS: Sera from ADAL and IFX patients with low drug levels (<1 mcg/mL) were analyzed by ACE, HMSA, and bridging assay. Neutralizing capacity was determined by competitive ligand-binding assay. RESULTS: HMSA and ACE detected high ADA levels in all ADAL (19/42) and IFX (27/64) samples with neutralizing capacity. ADA was also detected in most of the samples without neutralizing capacity, but levels were significantly lower (P < 0.0001). Receiver operator characteristic curve analysis demonstrated that for both assays, ADA levels were a strong discriminatory marker of neutralizing ADA (area under the curve > 0.9, P < 0.0001). Using a signal >8× background as a cut-point, neutralizing ADA could be identified with high specificity (HMSA > 95%, ACE > 85%) and sensitivity (HMSA > 70%, ACE > 80%). The detection of multimeric drug-ADA complexes after HMSA was also a highly specific marker (specificity > 95%) of neutralizing ADA in both ADAL and IFX patients. Results using ACE and HMSA were highly correlated. CONCLUSIONS: Results obtained after HMSA and ACE analysis are strongly correlated, and in both assays, high ADA levels are a specific marker of neutralizing capacity. The detection of multimeric complexes by HMSA also selectively identifies sera with neutralizing capacity. These data support the use of these assays as quantitative rather than simple qualitative measures of ADA.

Is N,N-dimethylglycine N-oxide a choline and betaine metabolite?

Choline metabolism is by oxidation to betaine, which is demethylated to N,N-dimethylglycine; dimethylglycine is oxidatively demethylated to sarcosine. This pathway is important for osmoregulation and as a source of methyl groups. We asked whether another metabolite was involved. We synthesized the N-oxide of dimethylglycine (DMGO) by oxidizing dimethylglycine with peracetic acid, and measured DMGO in human plasma and urine by HPLC-MS/MS with positive ion detection, using two chromatography procedures, based on ion exchange and HILIC separations. The molecular ion DMGOH+ (m/z=120) yielded four significant fragments (m/z=103, 102, 58 and 42). The suspected DMGO peak in human body fluids showed all these fragments, and co-chromatographed with added standard DMGO in both HPLC systems. Typical plasma concentrations of DMGO are under 1 µmol/l. They may be lower in metabolic syndrome patients. Urine concentrations are higher, and DMGO has a higher fractional clearance than dimethylglycine, betaine and choline. It was present in all of over 80 human urine and plasma samples assayed. Plasma DMGO concentrations correlate with plasma DMG concentrations, with betaine and choline concentrations, with the osmolyte myo-inositol, and strongly with urinary DMGO excretion. We conclude that DMGO is probably a normal human metabolite.

Variation of betaine, N,N-dimethylglycine, choline, glycerophosphorylcholine, taurine and trimethylamine-N-oxide in the plasma and urine of overweight people with type 2 diabetes over a two-year period.

BACKGROUND: Plasma betaine concentrations and urinary betaine excretions have high test-retest reliability. Abnormal betaine excretion is common in diabetes. We aimed to confirm the individuality of plasma betaine and urinary betaine excretion in an overweight population with type 2 diabetes and compare this with the individuality of other osmolytes, one-carbon metabolites and trimethylamine-N-oxide (TMAO), thus assessing their potential usefulness as disease markers. METHODS: Urine and plasma were collected from overweight subjects with type 2 diabetes at four time points over a two-year period. We measured the concentrations of the osmolytes: betaine, glycerophosphorylcholine (GPC) and taurine, as well as TMAO, and the one-carbon metabolites, N,N-dimethylglycine (DMG) and free choline. Samples were measured using tandem mass spectrometry (LC-MS/MS). RESULTS: Betaine showed a high degree of individuality (or test-retest reliability) in the plasma (index of individuality = 0.52) and urine (index of individuality = 0.45). Betaine in the plasma had positive and negative log-normal reference change values (RCVs) of 54% and -35%, respectively. The other osmolytes, taurine and GPC were more variable in the plasma of individuals compared to the urine. DMG and choline showed high individuality in the plasma and urine. TMAO was highly variable in the plasma and urine (log-normal RCVs ranging from 403% to -80% in plasma). CONCLUSIONS: Betaine is highly individual in overweight people with diabetes. Betaine, its metabolite DMG, and precursor choline showed more reliability than the osmolytes, GPC and taurine. The low reliability of TMAO suggests that a single TMAO measurement has low diagnostic value.

Betaine and Trimethylamine-N-Oxide as Predictors of Cardiovascular Outcomes Show Different Patterns in Diabetes Mellitus: An Observational Study.

BACKGROUND: Betaine is a major osmolyte, also important in methyl group metabolism. Concentrations of betaine, its metabolite dimethylglycine and analog trimethylamine-N-oxide (TMAO) in blood are cardiovascular risk markers. Diabetes disturbs betaine: does diabetes alter associations between betaine-related measures and cardiovascular risk? METHODS: Plasma samples were collected from 475 subjects four months after discharge following an acute coronary admission. Death (n = 81), secondary acute MI (n = 87), admission for heart failure (n = 85), unstable angina (n = 72) and all cardiovascular events (n = 283) were recorded (median follow-up: 1804 days). RESULTS: High and low metabolite concentrations were defined as top or bottom quintile of the total cohort. In subjects with diabetes (n = 79), high plasma betaine was associated with increased frequencies of events; significantly for heart failure, hazard ratio 3.1 (1.2-8.2) and all cardiovascular events, HR 2.8 (1.4-5.5). In subjects without diabetes (n = 396), low plasma betaine was associated with events; significantly for secondary myocardial infarction, HR 2.1 (1.2-3.6), unstable angina, HR 2.3 (1.3-4.0), and all cardiovascular events, HR 1.4 (1.0-1.9). In diabetes, high TMAO was a marker of all outcomes, HR 2.7 (1.1-7.1) for death, 4.0 (1.6-9.8) for myocardial infarction, 4.6 (2.0-10.7) for heart failure, 9.1 (2.8-29.7) for unstable angina and 2.0 (1.1-3.6) for all cardiovascular events. In subjects without diabetes TMAO was only significant for death, HR 2.7 (1.6-4.8) and heart failure, HR 1.9 (1.1-3.4). Adding the estimated glomerular filtration rate to Cox regression models tended to increase the apparent risks associated with low betaine. CONCLUSIONS: Elevated plasma betaine concentration is a marker of cardiovascular risk in diabetes; conversely low plasma betaine concentrations indicate increased risk in the absence of diabetes. We speculate that the difference reflects control of osmolyte retention in tissues. Elevated plasma TMAO is a strong risk marker in diabetes.

Fenofibrate causes elevation of betaine excretion but not excretion of other osmolytes by healthy adults.

BACKGROUND: Cross-sectional data suggest that bezafibrate increases betaine excretion in dyslipidemic patients. OBJECTIVE: We aimed to demonstrate that fenofibrate induces increased betaine excretion in normal subjects and explore whether other 1-carbon metabolites and osmolytes are similarly affected. METHODS: Urine was collected from 26 healthy adults before and after treatment with fenofibrate (145 mg/day for 6 weeks). Excretions of betaine, N,N-dimethylglycine, free choline, myo-inositol, taurine, trimethylamine-N-oxide, carnitine, and acetylcarnitine were measured by liquid chromatography with mass spectrometric detection. RESULTS: Fenofibrate increased the median betaine excretion from 7.5 to 25.8 mmol/mole creatinine (median increase 3-fold), P < .001. The median increase in N,N-dimethylglycine excretion was 2-fold (P < .001). Median choline excretion increased 12% (significant, P = .029). Participants with higher initial excretions tended to have larger increases (P < .001 in all 3 cases). Fenofibrate did not significantly change the median excretions of myo-inositol, taurine, trimethylamine-N-oxide, and carnitine. The excretion of acetylcarnitine decreased 4-fold on treatment, with no correlation between the baseline and after-treatment excretions. Changes in all urine components tested, except trimethylamine-N-oxide, positively correlated with changes in betaine excretion even when the median excretions before and after were not significantly different. CONCLUSIONS: Fibrates increase betaine, and to a lesser extent N,N-dimethylglycine and choline, excretion. Other osmolytes are not elevated. Because the increase in betaine excretion depends on the baseline excretion, large increases in excretion in the metabolic syndrome and diabetes (where baseline excretions are high) could be expected. Replacement with betaine supplements may be considered.

Extreme urinary betaine losses in type 2 diabetes combined with bezafibrate treatment are associated with losses of dimethylglycine and choline but not with increased losses of other osmolytes.

PURPOSE: Betaine deficiency is a probable cardiovascular risk factor and a cause of elevated homocysteine. Urinary betaine excretion is increased by fibrate treatment, and is also often elevated in diabetes. Does fibrate further increase betaine excretion in diabetes, and does it affect the plasma concentrations and excretions of related metabolites and of other osmolytes? METHODS: Samples from a previous study of type 2 diabetes were selected if participants were taking bezafibrate (n = 32). These samples were compared with participants matched for age and gender and not on a fibrate (comparator group, n = 64). Betaine, related metabolites, and osmolytes were measured in plasma and urine samples from these 96 participants. RESULTS: Median urinary betaine excretion in those on bezafibrate was 5-fold higher than in the comparator group (p < 0.001), itself 3.5-fold higher than the median reported for healthy populations. In the bezafibrate group, median dimethylglycine excretion was higher (9-fold, p < 0.001). Excretions of choline, and of the osmolytes myo-inositol, taurine and glycerophosphorylcholine, were not significantly different between groups. Some participants excreted more betaine than usual dietary intakes. Several betaine fractional clearances were >100 %. Betaine excretion correlated with excretions of the osmolytes myo-inositol and glycerophosphorylcholine, and also with the excretion of choline and N,N-dimethylglycine, but it was inconclusive whether these relationships were affected by bezafibrate therapy. CONCLUSIONS: Increased urinary betaine excretions in type 2 diabetes are further increased by fibrate treatment, sometimes to more than their dietary intake. Concurrent betaine supplementation may be beneficial.

Measurement of marine osmolytes in mammalian serum by liquid chromatography-tandem mass spectrometry.

Osmolytes are accumulated intracellularly to offset the effects of osmotic stress and protect cellular proteins against denaturation. Because different taxa accumulate different osmolytes, they can also be used as "dietary biomarkers" to study foraging. Potential osmolyte biomarkers include glycine betaine, trimethylamine N-oxide (TMAO), homarine, dimethylsulfoniopropionate (DMSP), and the osmolyte analog arsenobetaine (AsB). We present a liquid chromatography-tandem mass spectrometry (LC-MS/MS) assay for the simultaneous measurement of these osmolytes in serum or plasma. Varying concentrations of osmolytes were added to serum and samples and extracted in 90% acetonitrile and 10% methanol containing 10 µM deuterated internal standards (D(9)-glycine betaine, D(9)-trimethylamine-N-oxide, (13)C(2)-arsenobetaine, D(6)-DMSP, and D(4)-homarine). Analytes were separated on a normal-phase modified silica column and detected using isotope dilution tandem mass spectrometry in multiple reaction monitoring (MRM) mode. The assay was linear for all six compounds (r(2) values=0.983-0.996). Recoveries were greater than 85%, and precision for within-batch coefficients of variation (CVs) were less than 8.2% and between-batch CVs were less than 6.1%. Limits of detection ranged from 0.02 to 0.12 µmol/L. LC-MS/MS is a simple method with high throughput for measuring low levels of osmolytes that are often present in biological samples.

Trimethylaminuria: causes and diagnosis of a socially distressing condition.

Trimethylaminuria is a disorder in which the volatile, fish-smelling compound, trimethylamine (TMA) accumulates and is excreted in the urine, but is also found in the sweat and breath of these patients. Because many patients have associated body odours or halitosis, trimethylaminuria sufferers can meet serious difficulties in a social context, leading to other problems such as isolation and depression. TMA is formed by bacteria in the mammalian gut from reduction of compounds such as trimethylamine-N-oxide (TMAO) and choline. Primary trimethylaminuria sufferers have an inherited enzyme deficiency where TMA is not efficiently converted to the non-odorous TMAO in the liver. Secondary causes of trimethylaminuria have been described, sometimes accompanied by genetic variations. Diagnosis of trimethylaminuria requires the measurement of TMA and TMAO in urine, which should be collected after a high substrate meal in milder or intermittent cases, most simply, a marine-fish meal. The symptoms of trimethylaminuria can be improved by changes in the diet to avoid precursors, in particular TMAO which is found in high concentrations in marine fish. Treatment with antibiotics to control bacteria in the gut, or activated charcoal to sequester TMA, may also be beneficial.

Measurement of plasma free choline by high performance liquid chromatography with fluorescence detection following derivatization with 1-naphthyl isocyanate.

Choline is an essential nutrient which is difficult to measure because it has no native absorbance or fluorescence and only relatively unreactive functional groups. The method described here uses the reaction of the hydroxyl group on choline with 1-naphthyl isocyanate to form a stable cationic aromatic urethane that can be measured by high performance liquid chromatography (HPLC) on a cation exchange column, followed by fluorescence detection. The sample was directly added to acetonitrile and mixed with magnesium oxide and 1-naphthyl isocyanate. The 1-naphthylurethane choline derivative was separated by HPLC using a strong cation exchange column with a tetramethylammonium glycolate buffer in the mobile phase, and measured by fluorescence detection. The recoveries from blood plasma were over 94%. In this study an internal standard was not used, and quantification was achieved by calibration using standards containing known choline concentrations. The within batch and between batch coefficients of variation (CVs) were below 6%. The response was linear over the biological range investigated (8.9-58.9 micromol L(-1), r2=0.998). This is a technically simple method that can be carried out with an inexpensive HPLC system with fluorescence detection. It has sufficient sensitivity to measure choline in biological materials such as human plasma, and is suitable for processing batches of samples.

Separation of cationic aracyl derivatives of betaines and related compounds.

Cationic aracyl esters of betaines can be formed by alkylation with aracyl halides or trifluoromethanesulfonates. HPLC on a non-endcapped strong cation exchange (SCX) column gave high retention of these derivatives. Cation exchange HPLC may be carried out on a normal-phase (silica or alumina) column using a polar organic solvent (acetonitrile, propan-2-ol) containing an aqueous buffer with an organic cation and a hydrophilic anion. Selectivity is affected by the choice of organic solvent and buffer, e.g. alcohols decrease the retention times of hydroxybetaines such as carnitine. Retention is reduced by increasing the water content and the buffer concentration. Capillary electrophoresis migration times are affected by the choice of buffer anion, with low pH citrate buffers favoured.

A high performance liquid chromatographic method for the measurement of total carnitine in human plasma and urine.

Total carnitine in plasma and urine can be measured by high performance liquid chromatography (HPLC) using the novel fluorescent derivatisation reagents 6'-methoxynaphthacyl trifluoromethanesulfonate and 2'-phenanthrenacyl trifluoromethanesulfonate. Sample preparation for total carnitine analysis involves: extraction of plasma and urine in methanol, the optional addition of serine betaine as an internal standard, saponification of acyl carnitines with calcium hydroxide, followed by derivatisation with 6'-methoxynaphthacyl trifluoromethanesulfonate or 2'-phenanthrenacyl trifluoromethanesulfonate. The derivatives were separated using an alumina column and measured by fluorescence detection. The coefficient of variation was below 5% using internal standard calibration, and recoveries of acyl carnitines after saponification were over 90%. The total carnitine method was shown to be linear at biological levels for plasma (over the range 30-130 micromol/l) and urine (over the range 80-180 micromol/l). Advantages of this method include good precision, accuracy and linearity, the use of fluorescence to gain sensitivity, the small sample volume required and a relatively low sample preparation time.