Behavioral Health Research Center of the Southwest, 612 Encino Place NE, Albuquerque, NM 87102, USA
Received 8 April 2002; in revised form 15 October 2002; accepted 4 November 2002
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ABSTRACT |
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INTRODUCTION |
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Health care workers labour sometimes under extremely stressful working conditions, work long hours, and have access to controlled substances that are commonly misused (Drug Addiction in Health Care Professionals, 2002). Clearly, SM prevention and early intervention programmes are needed for this population of employees. Yet, data are limited on how many such programmes exist, and their effectiveness in preventing SM, or in intervening with substance-misusing health care professionals (Hoffmann et al., 1997
).
A large managed care organization (MCO) in the southwestern United States initiated an SM prevention programme, which was enhanced through the Workplace Managed Care Cooperative Agreement initiative funded by the Substance Abuse and Mental Health Services Administrations Center for Substance Abuse Prevention. Named Project WISE (Workplace Initiative in Substance Education), this intervention included relatively low-cost elements, such as SM awareness training, information on how to reduce drinking, and brief counselling (Lapham et al., 2000). This consecutive paper is the second of two evaluating Project WISE. The first paper described the intervention and presented results of the analysis of health risk appraisal (HRA) data (Lapham et al., 2003
). The present study evaluates the effects of Project WISE on employee assistance programme (EAP) referral rates for SM-related problems, health care utilization rates, on-the-job injury rates and job termination rates.
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METHODS |
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The MCO Patient Database, derived from the hospital billing database, provided dates and types of health care services rendered for each employee, and covered the full study period, from 1 July 1996 to 1 July 2000. The post-intervention period was from 1 September 1998 to 1 July 2000. The unit of analysis for this investigation was person-months of employment, the at risk period for an EAP referral, injury, job termination or medical service. Medical services were classified as non-SM in-patient visits, non-SM days in which one or more out-patient services were provided, and total days of in-patient or out-patient visits for SM-related reasons. SM diagnoses ICD-9 codes included misuse of alcohol and other drugs, excluding tobacco, and were selected and grouped based on criteria provided by the Workplace Managed Care Cross-site Evaluation Team and Workplace Managed Care Steering Committee (Galvin, 2000). ICD-9 codes indicating SM-related medical conditions for all in-patient and out-patient services were as follows: 291, 292, 303305, 357.5, 357.6, 425.5, 535.3, 571.0571.3, 571.5, 648.3, 655.4, 655.5, 760.7 (excluding 760.74 and 760.79), 779.5, 790.3, 962.0, 965.0, 967970, 977.0, 977.3, 980, V70.4 and V79.1. Non-SM-related utilization is defined as all visits where the primary, secondary or tertiary diagnoses did not contain any of the above ICD-9 codes. Injuries included in the analysis were limited to accidental injuries (i.e. excluding communicable diseases). All voluntary and involuntary job terminations, excluding those from a reduction in work force, were included in this analysis.
The mean number of events per person-month was calculated separately for the intervention and comparison sites before 1 September 1998, and after 1 September 1998. First, univariate comparisons were made using the KruskalWallis test among medians for each of the outcome measures. These tests were based on summary measures over all person-months and were not adjusted for differences in person-months employed. Then, average monthly events were calculated separately by the following predictors: group (intervention, comparison), time (pre-, post-), the interaction between group and time, and demographic factors including age (30, 3140,
41 years), gender and job class (professional/technical, executive administrative, administrative support, other). Finally, the effect of the intervention was evaluated statistically by fitting a logistic regression model for each outcome. This model compared intervention site employees, whose period of employment included the time after 1 September 1998, with all other employees, while adjusting for employment site and effects of time.
Each employee had multiple person-months, during which an event, such as an EAP referral or job termination, could occur. Data used throughout this analysis were longitudinal, and individual employee data were inter-correlated. Therefore, SAS/PROC GENMOD was used for analysis, as it allowed the use of generalized estimating equations (GEEs) for fitting repeated measures logistic regression models to each outcome measure in this analysis (Liang and Zeger, 1986). These estimation procedures provided unbiased parameter estimates and standard errors for repeated measures data. A similar analytical framework was recently used by Parthasarathy et al. (2001)
to study changes in health care utilization with alcohol and drug treatment.
The mean of each outcome measure [monthly EAP referral rates, monthly injury rates, monthly risk of job termination, SM-related in-patient utilization rates, SM-related out-patient utilization rates, non-SM in-patient days, non-SM days of out-patient visits, and emergency department (ED) utilization rates] was modelled as a function of the previously-listed predictors. Log odds ratios for each predictor were adjusted for all other terms in the model. Adjusted odds ratios estimated by the analysis were interpreted as approximate relative risks, averaged over the study population.
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RESULTS |
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Univariate comparisons of outcomes pre- and post-intervention
Univariate comparisons revealed that average SM-related EAP referral rates per employee decreased markedly in the comparison site, but showed a slight increase in rates at the intervention site (Table 2). Individual counts of EAP referrals for all reasons decreased from 246 total referrals pre-intervention to 163 post-intervention for the intervention site and from 179 total referrals pre-intervention to 90 post-intervention for the comparison site. The percentage of referrals for SM-related reasons increased from 8% of all referrals to 14.7% for the intervention site, but decreased from 10 to 1% for the comparison site in the post-intervention period. In-patient visits for SM-related conditions did not differ between the sites after the intervention was implemented. Out-patient SM utilization decreased at both sites (P < 0.001 for the overall differences) following implementation of the intervention. Average non-SM out-patient visit rates decreased over time at both sites, but the decrease was larger at the intervention site (P < 0.001 for the overall difference among medians). Average ED visit rates decreased over time at both sites. Average monthly injury rates increased at both sites, as did the monthly job termination incidents (P < 0.001 and P < 0.05, respectively).
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There was a large decrease in the non-SM in-patient utilization rates after 1 September 1998 (Table 3). Employees had monthly odds of in-patient utilization that were nearly half those before 1 September 1998. Furthermore, the intervention site had lower overall rates of in-patient utilization than the comparison site (OR = 0.74, P < 0.05). However, after 1 September 1998, employees at the intervention site had increased rates by a factor of 1.5 (P < 0.05). This mitigated the overall drop in utilization seen after 1 September 1998, for both workforces. Employees in the
30 age group had a significantly higher rate of in-patient utilization (OR = 1.4, P < 0.001), while men had a significantly lower rate of utilization (OR = 0.4, P < 0.001).
There was a slight historical trend toward lower non-SM out-patient utilization rates after 1 September 1998 (OR = 0.92, P < 0.01) (Table 4). This trend was apparent at both sites. The interaction effect of period at risk by site of employment was highly significant (P < 0.01) and suggests a greater decrease in the monthly rate (OR = 0.92) of non-SM out-patient utilization at the intervention site, once the intervention was in place. Table 4
shows a significant age effect on non-SM out-patient utilization monthly rates. Employees under the age of 41 years had significantly lower rates of out-patient utilization than employees in the oldest age group. Men also had nearly half the monthly odds of out-patient utilization as women (P < 0.001). All job classes in this analysis had approximately 1.3 times the odds of monthly out-patient utilization as the professional/technical employees.
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Injury rates. The increase in the average per-capita injury rate was marked after 1 September 1998 (Table 4). The odds of injury for those employed after that date were more than 1.7 times those employed prior to the date (P < 0.01). No significant site or site by time period effects were apparent here, however. Men had significantly lower on-the-job injury rates than women (OR = 0.69, P < 0.01), and employees in the executive/administrative job classes had much lower odds of injury than those in the professional/technical job class (OR = 0.29, P < 0.001).
Job loss. Intervention site employees had a significantly lower risk of losing their jobs than comparison site employees (OR = 0.82, P < 0.001) (Table 4). However, there was no site by time effect. The hazard of job termination increased with age, and employees in the administrative support job class had significantly greater risk of losing their jobs than employees in the professional/technical fields (OR = 1.13, P < 0.001).
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DISCUSSION |
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It was also hypothesized that the intervention may lead to increased health care utilization for SM treatment. Analysis of HRA data (see the preceding paper by Lapham et al., 2003) revealed that, among binge drinkers, the proportion of those who reported a desire to reduce drinking in the post-intervention period increased significantly. This effect was limited to those at the intervention site. Despite this, neither in-patient nor out-patient levels of service increased following the intervention. On the contrary, the out-patient utilization of SM treatment services dropped at both sites, following the intervention. If the prevention/intervention programmes were effective in persuading binge drinkers to reduce the number of days in which they drank heavily, it might have been that treatment services were not needed for these individuals. However, HRA data suggest that binge drinking rates were not affected by the Project WISE intervention. Studies have demonstrated that a large percentage of heavy drinkers reduce their alcohol intake on their own, without outside interventions (Walters, 2001
). A review of brief intervention programmes in health care settings, consisting of elements similar to those of Project WISE (providing information, brief advice, self-help manuals) can reduce drinking, especially among those who are less serious problem drinkers (Babor et al., 1986
; Bien et al., 1993
). Other explanations for the lower utilization of SM treatment services include system-wide changes in service delivery, low penetration of the intervention and/or reluctance of employees to identify themselves as having an SM problem. The latter is supported by focus group data showing that employees were suspicious of using in-house services in the event they developed SM problems and fearful that this information may not remain confidential (S. Lapham and N. O. Lewis, in preparation).
Many health care utilization events may be the result of illness and conditions not influenced by SM or risky drinking. ED utilizations may be reduced if substance misusers received intervention services, but did not change significantly over time after the intervention was introduced to the intervention site. A small increase in the rate of out-patient visits for SM was observed at the intervention site, although this effect was not significant at the 0.05 test level. A large positive trend toward increasing in-patient utilization rates and a small negative trend toward decreasing non-SM out-patient utilization were observed at the intervention site after the introduction of the intervention (P < 0.05). We could find no likely explanation for these unanticipated findings.
Project WISE had no demonstrated effect on job losses or injury rates, as might be anticipated with effective prevention programmes. However, Project WISE was short-lived, with a post-intervention evaluation period of only 22 months. The analysis was also complicated by a number of factors. First, data censoring was an unavoidable problem in this evaluation. The complete service uses and charges for some workers were not fully observed because of staff turnover. To address this problem, we calculated person-months as an adjusting variable in fitted models. Secondly, not all data sources were available for the entire study period because data were either not collected or lost. Staff turnover, a lack of a computerized record-keeping system prior to project initiation, and misplaced hard-copy files were noted as the reasons for missing data. Therefore, certain planned analyses (e.g. biochemical indicators of SM, absenteeism) were not possible. Missing from the retrospective data pool were workers compensation claims, absenteeism rates and job satisfaction survey data. EAP data were only partially available from January 1997 forward, at which time a computerized tracking system was initiated. Data collection for the EAP was truncated at 1 year post-intervention due to outsourcing of services.
In summary, health care workers should have SM prevention services available, as this employee group works in high stress environments with easy access to mood-altering chemicals. The implementation of Project WISE, an SM prevention/early intervention programme designed specifically for this population, was associated with a differential increase in SM-related EAP referrals at the intervention site, but not with differential increases in the provision of treatment services for SM-related problems, job loss or injury rates. This singular, but encouraging finding merits further study.
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ACKNOWLEDGEMENTS |
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FOOTNOTES |
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REFERENCES |
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