METHOD-DEPENDENT CHARACTERISTICS OF CARBOHYDRATE-DEFICIENT TRANSFERRIN MEASUREMENTS IN THE FOLLOW-UP OF ALCOHOLICS

Petra Anttila1, Kimmo Järvi2, Jaana Latvala1 and Onni Niemelä1,3,*

Departments of 1 Clinical Chemistry and 2 Psychiatry, EP Central Hospital, Seinäjoki and 3 University of Tampere, Tampere, Finland

* Author to whom correspondence should be addressed at: EP Central Hospital, Laboratory, FIN-60220 Seinäjoki, Finland. Tel.: +358 6 415 4719; Fax: +358 6 415 4924; Email: onni.niemela{at}epshp.fi

(Received 4 August 2003; first review notified 18 September 2003; in revised form 20 October 2003; accepted 29 October 2003)


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Aims: There are only limited data comparing the diagnostic characteristics of carbohydrate-deficient transferrin (CDT) measurements in assays for excessive alcohol consumption under controlled conditions. Methods: We compared different CDT assays and the conventional laboratory markers of ethanol consumption, {gamma}-glutamyl transferase (gamma-GT) aspartate aminotransferase (AST) and mean corpuscular volume (MCV) in the assessment and follow-up of 36 alcoholics (31 men, five women, mean age 44 years), who were admitted for detoxification. Detailed interviews to assess the amount of alcohol consumption were carried out for each patient. A hospital follow-up with supervised abstinence for 8 ± 4 days (range 5–19 days) was carried out for 17 patients. Controls were 30 apparently healthy individuals (22 men, eight women, mean age 49 years), who had no history of hazardous drinking. Results: At the time of admission, the %CDT method, which excludes the trisialotransferrin isoform from the measurement, yielded elevated values in 69% of the patients, compared to 61% for CDTect. The corresponding sensitivities for gamma-GT, AST and MCV were 61, 56 and 47%, respectively. The self-reported alcohol consumption for a period of 1 month prior to admission showed a stronger correlation with the %CDT results (r = 0.59, P = 0.0003) than with the CDTect results (r = 0.36, P = 0.04), GT (r = 0.40, P = 0.02) or AST (r = 0.35, P = 0.05). During follow-up with supervised abstinence the mean %CDT values were found to show a slower rate to normalization (mean 14 ± 4 days) than the CDT values measured with the CDTect method (mean 10 ± 5 days) (P < 0.05). Conclusions: The data indicate distinct differences and method-dependent rates of normalization in CDT assays, possibly reflecting different degrees of transferrin desialylation in the alcoholics. The present findings should be considered in studies on alcohol markers for monitoring abstinence.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Sialic acid-deficient isoforms of transferrin are known to increase as a result of excessive alcohol consumption. Such isoforms have traditionally been referred to as CDT (carbohydrate-deficient transferrin, desialotransferrin), and their measurements have been widely used as diagnostic tools for detecting alcohol-related health problems. However, the interpretations of the assay results have suffered from a lack of uniform international standardization (Arndt, 2001Go; Helander et al., 2001Go; Conigrave et al., 2002Go; Helander, 2002Go; Tagliaro et al., 2002Go). In healthy people, the most common transferrin isoform is tetrasialotransferrin, whereas in alcoholics, various degrees of sialic acid-deficient isoforms are generated (Stibler, 1991Go; Allen et al., 1994Go; Helander et al., 2001Go). Usually, the definition of CDT has referred to those with 0–2 or 0–3 sialic acid side chains (Stibler, 1991Go; Allen et al., 1994Go; Arndt, 2001Go; Helander, 2002Go).

Various methods with different reactivities to different transferrin isoforms are currently available. The diagnostic characteristics of such methods in the clinical assays for detecting alcohol misuse have, however, not been fully established (Scouller et al., 2000Go). The new %CDT assay, which excludes the trisialo isoform (the isoform with three sialic acid side chains) from the measurement, has recently been suggested to yield improved specificity as compared to the conventional CDTect method, which has previously been the most widely used CDT assay (Anton et al., 2001Go).

We designed this study to compare the characteristics of the different CDT methods in the detection and follow-up of alcoholics, who were admitted for detoxification. For comparison, the conventional alcohol markers (GT, AST, MCV) were also measured. The data suggest distinct differences between the different CDT assays in monitoring alcohol drinking and abstinence.


    MATERIALS AND METHODS
 TOP
 ABSTRACT
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Patients and control subjects
We studied 36 heavy drinkers (31 men, 5 women, mean age 44 ± 10; range 24–65 years), who were admitted for detoxification, and 30 apparently healthy control subjects (22 men, 8 women, mean age 49 ± 13; range 27–75 years). All the alcoholic patients showed a well-documented history of continuous alcohol consumption or binge drinking, which consisted of 132 ± 71 (mean ± SD) g/day during the 4-week period prior to sampling. The documentation of alcohol misuse was based on detailed personal interviews using a time-line follow-back technique. The patients were asked how many drinks of alcohol (standard drink = 12 g of ethyl alcohol corresponding to one beer, one glass of table wine or 3 cl 40% proof spirit) they had consumed during the: (1) 24 h, (2) 1 week and (3) 4 weeks preceding admission. The mean duration of abstinence prior to sampling was 1.8 ± 2.0 (range 0–6) days. A follow-up with supervised abstinence during hospitalization for 8 ± 4 (range 5–19) days was carried out with 17 patients. Blood-alcohol concentrations were controlled by repeated analyses from breath air. The main clinical and laboratory characteristics of the study population are summarized in Table 1.


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Table 1. Clinical and laboratory characteristics of the study population

 
The controls were either abstainers (n = 20; 16 men, four women, mean age 47 ± 9 years) or social drinkers (n = 10; six men, four women, mean age 55 ± 12 years) whose mean daily ethanol consumption did not exceed a mean of 15 g ethanol per day or 40 g on any single occasion.

All serum samples were stored at –70°C until analysis. All participants in the study gave their informed consent and the study was carried out according to the provisions of the Declaration of Helsinki.

CDT analyses
The concentration of CDT was measured in serum samples by two different methods. First, a turbidimetric immunoassay after ion-exchange chromatography (%CDT; Axis-Shield, Oslo, Norway), which detects transferrin variants with 0–2 sialic acid residues, was used. In this assay, CDT concentration is expressed as a percentage of the total amount of serum transferrin. The measurements were carried out on Behring Nephelometer II (Dade Behring; Behring Diagnostics, Marburg, Germany) according to the instructions of the manufacturer's. Amounts exceeding 2.60% were considered high (Anton et al., 2001Go). In addition, CDT was measured by a competitive radioimmunoassay after micro-column separation (CDTect). In this assay, serum transferrin isoforms with 0–1 sialic acid residues ({alpha}- and monosialotransferrins) and minor amounts of isotransferrin with two sialic acid residues (disialotransferrin) are detected. The reference range is 0–20 U/l for men and 0–26 U/l for women (Anton et al., 2001Go; Helander, 2002Go).

Other methods
Serum {gamma}-glutamyl tansferase (GT), aspartate aminotransferase (AST), alanine aminotransferase (ALT), albumin, bilirubin and mean corpuscular volume (MCV) of erythrocytes were measured by standard clinical chemical methods in an accredited (SFS-EN 45001, ISO/IEC Guide 25) laboratory of EP Central Hospital, Seinäjoki, Finland. The reference ranges for these parameters were as follows. GT, men <80 U/l, women <50 U/l; AST, men <50 U/l, women <35 U/l; ALT, men <50 U/l, women <35 U/l; albumin 36–50 g/l; bilirubin 2–20 µmol/l; MCV 76–96 fl.

Calculations and statistical methods
The data are expressed as means ± SD. The comparisons between the alcoholic and non-alcoholic groups were carried out using Student's t-test or the Mann–Whitney test for parameters with skewed distributions of values. Comparisons of the analytical characteristics between the different markers were based on ROC-assays using Analyse-it software (Analyse-it Software, Leeds, UK) Calculations of marker normalization rates were based on observed values and related to the starting value and to the time point of the last drink. Correlations were calculated using the Pearson product–moment correlation coefficients. A P-value less than 0.05 was considered statistically significant.


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
At the time of admission, the markers of ethanol consumption in 36 alcoholic patients with a mean ethanol consumption of 132 ± 71 g/day and a mean duration of abstinence of 1.8 ± 2.0 days were all significantly higher than those of the control population (Table 1). When the controls were further divided into subgroups of social drinkers (n = 20) and abstainers (n = 10), the mean %CDT (2.0 ± 0.4, 2.0 ± 0.4), CDTect (12 ± 4, 17 ± 7), GT (27 ± 11, 23 ± 10) or AST (32 ± 24, 26 ± 8) values were not found to be significantly different between these subgroups, respectively.

Elevated marker values in the alcoholics at the time of admission were observed with the following frequencies: %CDT 69%, CDTect 61%, GT 61%, AST 56% and MCV 47%. Except for MCV, the differences in the analytical characteristics between the above marker pairs were not statistically significant. Serum bilirubin and albumin did not differ significantly between the alcoholic and control populations, suggesting a lack of significant liver dysfunction in the present sample of alcoholic patients (Table 1). The amount of alcohol consumed, as estimated by a time-line follow-back method from different time intervals prior to sampling, correlated most significantly with the %CDT and MCV results (Table 2).


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Table 2. Correlation between the different marker values at the time of admission and the amount of alcohol used prior to sampling

 
A follow-up with supervised abstinence during hospitalization for 8 ± 4 (range 5–19) days was completed for 17 patients. At the initiation of this follow-up, %CDT was elevated in 77%, CDTect in 71%, GT in 47%, AST in 47% and MCV in 53% of the patients. All markers except for MCV and AST, decreased significantly during abstinence, as reflected both in the incidence of abnormal values (Fig. 1) or marker concentrations (Table 3). Interestingly, during the follow-up CDT concentrations in repeated sampling were found to show different rates to normalization with the two methods (14 ± 4 days for %CDT and 10 ± 5 days for the CDTect) (P < 0.05). At the end of the follow-up, %CDT values remained elevated in 65% of the cases, whereas CDTect remained elevated only in 47% of the patients. The corresponding percentages for serum GT, AST and MCV were 35, 47 and 59%, respectively. Among the individual patients, %CDT gave a lower value for all patients after abstinence whereas with CDTect, GT and AST occult marker elevations were also seen (Figs 2 and 3).



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Fig. 1. The proportions of elevated values in various laboratory markers of alcohol consumption in the alcoholics at the time of admission (black) and after a mean of 8 ± 4 days of supervised abstinence (grey). CDT, carbohydrate-deficient transferrin; GT, {gamma}-glutamyl transferase; AST, aspartate aminotransferase; MCV, mean corpuscular volume.

 

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Table 3. Changes in marker values during follow-up of alcoholics with supervised abstinence

 


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Fig. 2. Individual CDT values at the beginning and end of the follow-up period in the alcoholic patients, as assessed with the two different methods. The follow-up period was 8 ± 4 days. A, at admission; B, at end of follow-up period.

 


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Fig. 3. The proportions of alcohol marker values showing increases (A) or decreases (B) after the follow-up period. For abbreviations and details, see legend to Figure 1.

 

    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
The present data indicate that the CDT assays, which have different reactivities towards the different desialylated isoforms of transferrin, show different analytical characteristics in the assessment and follow-up of alcohol misusers. Although CDT measurements have been widely employed in alcohol screening programmes, the methods have been heterogeneous and the data on their clinical sensitivities have remained controversial, with reports ranging from <20 to 100% (Stibler, 1991Go; Nyström et al., 1992Go; Allen et al., 1994Go; Bean et al., 1997Go; Salaspuro, 1999Go; Scouller et al., 2000Go; Arndt, 2001Go; Helander et al., 2001Go; Sillanaukee et al., 2001Go; Conigrave et al., 2002Go). Therefore, there is an apparent need for further work on methodological standardization and method comparisons.

Most of the current knowledge on CDT measurements has been based on the use of the conventional CDTect method. The more recently introduced %CDT measurements have offered the benefit of expressing the data conveniently as percentages of total transferrin with similar cut-offs for both sexes. However, the first versions of the %CDT assays suffered from poor analytical sensitivities (Viitala et al., 1998Go). More recent comparisons between the new %CDT and CDTect methods have shown essentially similar sensitivities (Anton et al., 2001Go). Accordingly, the new %CDT method in the present relatively small material appears to yield even a slightly higher (although not statistically significant) sensitivity (69%) than the conventional CDTect method (61%) or the other conventional markers of ethanol consumption (Fig. 1) when analysed at the time of admission. It may be emphasized that, in assays for alcohol misuse, which has an extremely high prevalence (typically 10–20% in many Western countries), even a small improvement in the analytical performance should lead to a more correct identification of a large number of hazardous drinkers, which, in turn, is of crucial importance in the clinical assessment of such patients. However, as the current material is relatively small future studies for testing marker function in larger materials appear warranted.

Interestingly, current data also show that the correlation between the marker results and the actual amount of ethanol consumed is stronger with the %CDT results than with the CDTect results, indicating that the measurements (which exclude the trisialofraction but include the entire disialofraction into the measurement) may reflect ethanol-induced changes in transferrin protein in a more specific manner. This may also be due to the fact that the CDTect method may respond to unspecific changes in transferrin protein metabolism, iron balance, or hormonal status (Niemelä et al., 1995Go; Sorvajärvi et al., 1996Go; De Feo et al., 1999Go; DiMartini et al., 2001Go; Whitfield et al., 2001Go). Such phenomena may also explain the previously reported poor sensitivities for CDTect assays in female patients (Anton and Moak, 1994Go; Löf et al., 1994Go; Reif et al., 2001Go; Anton et al., 2002Go). Preliminary analyses of serum sialic acid contents from these patients have indicated no significant relationship between the assay-dependent characteristics and sialic acid metabolism (data not shown).

In this study we included both abstainers and social drinkers in our control material. No significant differences in CDT values emerged between these subgroups, suggesting a lack of correlation between the consumption of low doses of alcohol and CDT values. In the alcoholics, the presence of severe liver disease has previously been found to be a significant confounding variable in the interpretation of CDT results (Anttila et al., 2003Go). In this study the possible effect of alcohol-related liver disease on the findings could not be assessed by the method-of-choice, because liver biopsies were not done. It should be noted, however, that based on clinical examination and laboratory findings indicating that serum bilirubin and albumin levels were not significantly different between the alcoholics and controls, the former group should have been devoid of any significant liver dysfunction.

The present follow-up data show a consistent decrease of the %CDT marker values during abstinence, which is also in line with the view that the %CDT results show a close association between the marker data and drinking habits. The discrepancies between GT, CDTect, AST and abstinence perhaps could be due to induction of liver pathology, which may be reflected in marker values also during abstinence. In particular, the CDTect method may be sensitive to changes occurring during liver pathology even in its early phase (Tsutsumi et al., 1994Go; Niemelä et al., 1995Go). The present findings indicating that CDT methods may also have kinetic differences in their rates of normalization should also be considered in further method comparisons and in monitoring abstinence in alcoholic patients.


    ACKNOWLEDGEMENTS
 
This study was supported in part by a grant from the Finnish Foundation for Alcohol Studies.


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