Abstract
Objective: To determine the influence of clinical, laboratory, and electrodiagnostic factors on the prognosis of Guillain-Barré syndrome (GBS).
Background: Identification of prognostic factors may lead to better selection of patients with a poor prognosis for new therapeutic trials.
Methods: The authors studied 147 patients with GBS who participated in the Dutch GBS trial comparing the effect of IV immunoglobulins with plasma exchange (PE). Outcome was measured at 8 weeks because half of the patients had recovered independent locomotion by then and at 6 months, the endpoint of the study.
Results: Multivariate logistic regression revealed the following factors predicting outcome (inability to walk independently) at 8 weeks: a preceding gastrointestinal illness (yes, no), age (≥50, <50 years), Medical Research Council sum score (<40, ≥40) at the start of treatment, and—described for the first time—a recent cytomegalovirus (CMV) infection (yes, no). At 6 months, the same clinical factors were found, but an initial rapid progression of weakness also appeared to be a prognostic factor. Analysis of treatment interactions revealed that the effect of diarrhea was more pronounced in the PE-treated group.
Conclusions: The main predictors of outcome in GBS are clinical factors. Diarrhea is an important poor predictor of outcome, especially for the PE-treated group, and a recent CMV infection predicts delayed early recovery.
Guillain-Barré syndrome (GBS) is an acute immune-mediated disease of the peripheral nervous system with a wide range of clinical symptoms and great variability in outcome. Artificial respiration is required in 10 to 35% of patients and 5 to 10% may have permanent disabling weakness, imbalance, or sensory loss.1-3 Plasma exchange (PE) improves the early outcome, and high-dose IV immunoglobulin (IVIg) has been shown to be at least as effective as PE.4,5 Although IVIg is potentially a safer and more convenient treatment, morbidity is still considerable. For those with a poor prognosis, additional treatment needs to be developed. Therefore, identification of easily obtainable prognostic factors has therapeutic implications. Furthermore, prediction of the clinical course may help to improve the information and support available to the individual patient. Until now, severely reduced muscle action potential amplitude on myography,6-10 older age,6,8,10-12 need for ventilatory support,6,8,9,12 and a severe, rapidly progressive course of disease6,8,9,12-14 have been associated with a poor outcome in studies using multivariate analysis. In this study using data from the Dutch GBS trial, logistic regression was performed, first using clinical factors and then adding ancillary investigations, such as antecedent infections, anti-GM1 antibodies, and longitudinally performed electrodiagnostic studies.
The study was performed 1) to confirm previous factors related to a poor outcome and to assess new prognostic factors; 2) to identify prognostic factors of patients with GBS after IVIg treatment and to determine differences in prognostic factors between IVIg and PE; and 3) to construct practical models to predict short-term outcome (at 8 weeks) and outcome at 6 months.
Methods.
Outline of the study.
All patients were entered into the Dutch GBS trial, a multicenter clinical trial comparing the effect of IVIg and PE, the background, design, and results of which have been published elsewhere.4
Clinical assessment at start of treatment.
Before treatment began, the following features were determined: age, sex, antecedent episodes in the 4 weeks before onset of weakness (a gastrointestinal or upper respiratory tract infection), time from onset of weakness until start of treatment, distribution of muscle weakness (predominantly distal, proximal, global, or mixed according to the method described elsewhere),15 functional (F) score,4 Medical Research Council (MRC) sum score,16 and presence of sensory loss and cranial nerve deficits.
Clinical assessment during follow-up.
During follow-up, the F score, MRC sum score, and presence of cranial nerve palsies were determined three times a week during weeks 1 and 2, once a week up to week 6, and in weeks 8, 10, 14, 18, 22, and 26. The method of assessment of severity of sensory loss (none, mild, or severe) during the first 2 weeks of follow-up is described elsewhere.17 The 147 patients with GBS were followed up in a prospective study, and the highest functional score, lowest MRC sum score, severity of sensory loss at nadir, and time until the lowest MRC sum score (time until nadir) were determined from the data. These factors were known within the first 2 weeks of follow-up.
Electrodiagnostic studies at start of treatment and during follow-up.
Electrodiagnostic testing (electromyography [EMG]) was performed using standardized conventional techniques at entry and at 1 and 4 weeks after randomization. The details of testing have already been reported.18 Because other studies emphasized the importance of the prognostic value of electrophysiologic data,6-8 these variables were tested extensively. We used the amplitude of the compound muscle action potential (CMAP) of the abductor pollicis brevis muscle after distal stimulation of the median nerve, the CMAP of the abductor digiti quinti muscle after distal stimulation of the ulnar nerve, and the sum of these CMAPs. The EMG data obtained at randomization and 1 week later were used.
Improvement of the distal CMAPs after stimulation of the ulnar and median nerves was also taken into account. CMAP improvement after 1 week was established when the increase in the CMAP of the individual nerves at the second investigation was >1 mV compared with the first EMG, and the summed CMAP improved by >2 mV. The peroneal nerve was tested in only 52 patients, and recruitment pattern on maximal voluntary effort, an important prognostic factor in univariate analysis,19 was available for only 101 patients. These data were therefore excluded from the analyses.
Laboratory studies before onset of treatment.
All available pretreatment samples were retested by ELISA for the presence of IgA, IgM, and IgG antibodies to Campylobacter jejuni, using an acid-glycine extract from C. jejuni as antigen.20 The ELISA to detect IgA, IgM, and IgG antibodies to ganglioside GM1 was also optimized, and thin-layer chromatography was used for confirmation.20 IgM antibodies against cytomegalovirus (CMV) in the initial serum samples were determined by ELISA (Vidas; bioMésieux, Mercy-l’Etoile, France).
Statistical methods.
End points were the ability to walk independently at 8 weeks and at 6 months. Eight weeks was chosen as one end point because half of the 147 patients were able to walk independently at this point. The final clinical assessment was performed at 6 months. Patients unable to walk independently at this stage are likely to have considerable permanent clinical deficits.
The identification of prognostic factors for each combination of binary outcome (ability to walk independently at 8 weeks and 6 months) and set of potential prognostic factors was performed using the following strategy.
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1. All continuous variables were analyzed with respect to representation (continuous or categorized). An appropriate coding system was devised by creating four categories of continuous variables based on the quartiles of their distribution. With univariate logistic regression on the three dummy variables derived from the four categories, the log odds ratios (ORs) were calculated. Plots of these log ORs versus the categories were used as an empirical assessment of a linear (or quadratic) relation of the log ORs with the factor of concern. Factors with three categories were recoded to two dummy variables.
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2. Univariate associations for each factor separately were assessed with the chi-square test (a two-tailed test) without correction for continuity.
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3. Forward and backward stepwise logistic regressions were applied with two different sets of entry and drop criteria: p-enter = 0.25, p-remove = 0.35 and p-enter = 0.15, p-remove = 0.20. Only factors with significant (p < 0.05, Wald test) coefficients were finally maintained.
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4. For the selected factors, the interaction with treatment was incorporated into the model when significant (p < 0.05).
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5. The overall fit of the model was studied using the Hosmer-Lemeshow test.
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6. The model’s accuracy was determined using a receiver operating characteristic (ROC) analysis and by calculation of the area under the ROC curve. The heuristic shrinkage estimator of van Houwelingen and le Cessie21 was used to quantify overfitting.
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7. For each selected model, the predicted probabilities for each covariate pattern (i.e., a combination of outcomes of prognostic factors) was calculated, with and without correction for overfitting (shrinkage).
The available data were tested in rank order according to the sequence in which they became available in the clinical setting. The clinical features were analyzed first, followed by the EMG and laboratory findings.
To illustrate the effect of prognostic factors, time to reach the stage of independent locomotion between the different groups was analyzed by the method of Kaplan and Meier and the log-rank test.
Results.
Univariate analysis of factors influencing outcome at 8 weeks and 6 months.
Table 1 summarizes the results of the univariate analyses of baseline characteristics. Exploring the continuous prognostic factors did not reveal a linear or quadratic relation for the log ORs; therefore, we preferred dichotomization. Cutoff points were based on literature or median values. Of all potential prognostic clinical factors evaluated, age ≥50 years, MRC sums core <40, a preceding gastrointestinal illness, and being bedbound or on the ventilator were associated with a significantly increased risk of being unable to walk independently 8 weeks or 6 months after the start of therapy. An upper respiratory tract infection was related to an improved outcome 8 weeks after the start of treatment, but did not remain significant at the 6-month end point. Rapid onset of weakness (≤4 days) before the start of treatment resulted in a poor outcome only at 6 months, and was not of significance at 8 weeks.
Univariate analysis of clinical, electrodiagnostic, and laboratory factors known at entry and associated with the ability to walk independently at 8 weeks and 6 months after start of treatment
Table 1 also summarizes the univariate analysis of prognostic factors obtained by ancillary investigations done at randomization. A CMAP of the abductor digiti quinti of ≤3 mV was associated with a poorer outcome at both 8 weeks and 6 months; a CMAP of the abductor pollicis brevis of ≤3 mV was not a prognostic factor; and a value for the sum of the CMAPs of ≤6 mV was a relevant prognostic factor only at 8 weeks. Presence of anti-GM1 antibodies reached statistical significance at 6 months, and a recent C. jejuni infection was strongly associated with a poor outcome at that stage.
Table 2 gives details of the univariate analysis of the clinical and EMG data obtained during the first 2 weeks of follow-up (at nadir). An MRC sum score of ≤30 and need for artificial ventilation during follow-up were associated with decreased recovery. A low CMAP after distal stimulation of the ulnar nerve and median nerve and a low sum of these potentials obtained 1 week after randomization were all strongly related to a poorer recovery. Improvement of the amplitude by >1 mV between the first and second EMG indicated improved outcome (table 2).
Univariate analysis of clinical, electrodiagnostic, and laboratory factors known at nadir and associated with the ability to walk independently 6 months after start of treatment
Multivariate analysis of factors influencing outcome at 8 weeks and 6 months.
Both the MRC sum score and the F score are measurements of the severity of muscle weakness. We found that the MRC sum score was a more powerful predictor of outcome, and therefore chose it for the multivariate logistic regression analyses. Using all clinical factors known at the time treatment started, multivariate analysis revealed that age ≥50 years, a preceding gastrointestinal illness, an MRC sum score of <40, and absence of cranial nerve involvement remained independent factors indicating a poor prognosis at 8 weeks, whereas a preceding upper respiratory tract infection was related to an improved outcome. These five factors were put in a final model, and three of them remained independently significant: age ≥50 years, a preceding gastrointestinal illness, and MRC sum score of <40. These factors were then evaluated for treatment interactions, and it was found that the effect of diarrhea was more striking in the PE-treated group. Table 3 shows the ORs for the different prognostic factors. After inclusion of the laboratory data, one additional independent prognostic factor could be found; a recent CMV infection indicated a poor outcome at 8 weeks (table 3). The EMG data did not give rise to additional independent risk factors.
Clinical and laboratory factors known at start of treatment related to inability to walk independently 8 weeks and 6 months after onset of therapy (based on multivariate logistic regression)
Clinical factors that remained of prognostic importance at the 6-month end point were older age (≥50 years), a low MRC sum score (<40), diarrhea, and a rapid onset of weakness until start of treatment (≤4 days; table 3).
These factors in relation to the proportion of patients who did not achieve independent locomotion are shown in the Kaplan-Meier curves (figure). The effect of diarrhea is shown for each treatment separately (figure, A and B).
Figure. Kaplan-Meier curves indicating the proportion of patients who did not recover to independent locomotion (F = 2) during 181 days of follow-up, according to prognostic factors: (A) presence (n = 16) or absence (n = 57) of diarrhea for plasma exchange (PE) treatment, p (log-rank) = 0.0004; (B) presence (n = 11) or absence (n = 63) of diarrhea for intravenous immune globulin (IVIg) treatment, p (log-rank) = 0.19; (C) age <50 years (n = 74) or ≥50 years (n = 73), p (log-rank) = 0.003; (D) MRC sum score <40 (n = 73) or ≥40 (n = 74), p (log-rank) < 0.0001; (E) time of onset of weakness ≤4 days (n = 53) or >4 days (n = 60), p (log-rank) = 0.08.
Addition of the ancillary laboratory or EMG factors revealed no new independent prognostic factors. The calculated areas under the ROC curve for the four selected models range from 0.73 to 0.81. The four selected models all had a good fit (Hosmer-Lemeshow test p > 0.25).
Prediction of probabilities.
For each of the four models in table 3, the predicted probabilities of being able to walk independently (after 8 weeks or 6 months) can be calculated using the logistic model. Because of its limited value due to problems of overfitting (the number of potential prognostic factors is large in relation to the total number of patients; see, e.g., Harrell et al.22), we present only the results of the first model: three clinical factors as predictors for improvement at 8 weeks. The prognostic index for an individual patient can be calculated as follows: index = 0.30 − 1.04 × age (age < 50 years = 0, age ≥50 = 1) + 0.93 × MRC sum score (<40 = 0, ≥40 = 1) − 2.42 × diarrhea (no = 0, yes = 1) + 2.05 × diarrhea × treatment (no diarrhea = 0, treatment with PE = 0, diarrhea and treatment with IVIg = 1). For example, a patient treated with PE, 50 years of age or older, with an MRC sum score at entry of <40, and diarrhea, has a prognostic index of 0.30 − 1.04 × 1 + 0.93 × 0 − 2.42 × 1 + 2.05 × 0 = −3.16.
The probability of being able to walk independently after 8 weeks is calculated by 1/(1 + exp[−index]), or 4% in this example.
Overfitting is corrected by multiplying the prognostic index with the heuristic shrinkage factor,21 which was 0.43 for this model. This results in a corrected probability of 1/(1 + exp[−0.43 × (−3.16)]) = 20%.
Table 4 shows the predicted probabilities for each treatment for a patient with a poor prognosis and a patient with a good prognosis. Note that the overfitting-corrected probabilities move in the direction of the overall outcome.
Probability of the ability to walk independently at 8 weeks
Discussion.
This multivariate analysis of clinical, EMG, and laboratory data of 147 patients with GBS participating in the Dutch GBS trial produced several new findings important for predicting outcome in the patient with GBS. In this study, the patients were followed up in a prospective study and closely monitored according to a predefined protocol, the laboratory results were obtained from pretreatment serum samples, and electrodiagnostic testing was performed serially, at randomization and 1 week later.4,18 The available data were then tested in rank order according to the sequence in which they became available in the clinical setting. This different method of obtaining and analyzing the data may explain certain differences in predictors of outcome compared with other studies on the prognosis of patients with GBS.
The analysis dealing with early outcome (8 weeks) revealed the following independent predictors of poor outcome (inability to walk independently): a preceding gastrointestinal illness, older age (≥50 years), a low MRC sum score (<40), and a recent CMV infection. The same clinical factors were found at the 6-month end point, with the additional factor of a rapid onset of weakness (≤4 days until F ≥ 3). Most important, we found a difference between PE and IVIg because diarrhea was a more important predictor of poor prognosis in the PE group. Using these easily obtainable factors, the chance of being able to walk independently 8 weeks and 6 months after the start of treatment with IVIg or PE can be estimated.
The number of variables and interactions studied was relatively high in relation to the total number of patients. This may result in overfitting of the data, and consequently less accurate estimates of predicted probabilities.22 Correction for overfitting, based on the principle of shrinkage,21 were used to obtain more realistic estimates. However, it is clear that the best way to validate our model will be to use new data, which will be available in the near future from the ongoing IVIg-methylprednisolone trial.
Of the treatment studies dealing with prognosis in GBS, only the North American study6 looked at prognosis at 8 to 12 weeks. The researchers also found that severity of muscle weakness, indicated by respiratory insufficiency and older age, were related to a poor outcome.6 In their analysis, they did not consider the other factors of prognostic importance we determined: history of a gastrointestinal illness and laboratory support of recent CMV infection.
The prognostic value of positive IgM CMV serology in predicting early outcome has not been reported before; other studies looked at outcome at 6 or 12 months8 or did not add this factor into multivariate analysis.6,9-11 Our result needs to be replicated by others before it can be used in clinical practice. Recently, we emphasized the clinical and prognostic importance of the assessment of a recent CMV infection in GBS.17 Although in general patients with CMV-related GBS initially have a fulminant course, most of the patients recover at a later stage. This may be due to these patients’ younger age.17
In contrast to other studies,6,7,9,10 the neurophysiologic data did not help in the assessment of prognosis. Although technical differences may explain some of the results, it is more likely that other factors, such as severity of muscle weakness and diarrhea, overshadow the importance of EMG findings, especially if the muscle weakness assessment is performed at the same time as the EMG studies.
The most powerful predictor of outcome for early and intermediate recovery was an antecedent episode of diarrhea. Only three recent studies indicated that a history of diarrhea is associated with poor outcome.11,12,14 The studies with a large number of patients with GBS that dealt with prognosis did not take this factor into account.6,8
Although diarrhea and C. jejuni infection were analyzed as independent factors, they are in fact strongly related to each other. Seventy-five percent of the patients with diarrhea had positive C. jejuni serology, yet only half of the patients with positive serology had preceding diarrhea. Furthermore, C. jejuni has been found to be associated with motor GBS and anti-GM1 antibodies.12,15 Because of the close relation between these factors in the multivariate analysis, only diarrhea remained statistically significant in the final models.
Diarrhea is a significant factor for a poor prognosis, whereas an interaction with treatment was found using logistic regression analysis. The effect of diarrhea is more noticeable in the PE-treated group (table 3). This effect can also be shown with Kaplan-Meier curves (figure, A and B), although use of a log-rank test for diarrhea in the IVIg-treated group results in a p value of >0.05. This can be explained because 1) with this test a different end point is used, and 2) the log-rank is less efficient than the logistic model. This treatment interaction has to be confirmed by other studies because this result has been obtained by relative modeling of many factors in relation to sample size, which has its limitations. All patients with diarrhea and with poor outcome received the full regimen of PE.
An important prognostic factor was the severity of muscle weakness determined by the MRC sum score. Severity of muscle weakness as a prognostic factor, usually indicated by need for artificial respiration, has also been emphasized in other studies.6,23,24 This has important implications for deciding at which stage of the disease to start treatment. Both the French and North American studies concluded that PE in GBS is most effective when carried out early in the course of the disease.24,25 The aim should be to halt the progression of disease as soon as possible, and this has to be balanced against the costs. The severity of weakness is the only factor that can be influenced, because age and antecedent infections are unchangeable prognostic factors. Outcome might be improved if treatment is given when the patient does not have severe weakness or is started early in those with a rapid progression. Seventy-three of the 147 patients had an MRC sum score of <40 at start of treatment, and the median time from onset of muscle weakness until start of treatment was 5.5 (4.6 to 6.2) days in this group. This finding indicates that treatment in these patients could have been started earlier. Therefore, early recognition and treatment may be of importance for the long-term prognosis. Thirteen of these 73 (17%) patients who had an MRC sum score of <40 were bedbound within 48 hours after onset of muscle weakness. For this group, therapy should especially be focused on new or additional treatment.
Because IVIg is readily available and easily applicable and has far fewer side effects than PE,4,5,26 there will certainly be a tendency to treat patients with GBS at an early stage of the disease. Our policy is to monitor the patient as soon as possible and to start treatment no later than when the patient is no longer able to walk 10 m independently (F = 3). Our data suggest treating patients with a rapid progressive course, older age, or diarrhea as early as possible.
The French GBS Study Group recently determined the effect of PE in “mildly” affected patients with GBS.27 This study showed that two sessions of PE result in earlier recovery compared with no treatment. Moreover, patients with moderate and severe forms benefited from two additional exchanges. Similar studies should be performed to evaluate the optimal dose of IVIg in relation to the severity of muscle weakness in GBS.
Footnotes
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The PE-IVIg study was funded in part by Baxter Healthcare Cooperation, Hyland Division and the American Red Cross.
- Received July 31, 1997.
- Accepted March 27, 1999.
References
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