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Characteristics of Mothers Who Have Children with Fetal Alcohol Syndrome or Some Characteristics of Fetal Alcohol Syndrome

From the Aberdeen Area Indian Health Service (VLK, TKW), Public Health Service Indian Hospital, Rapid City, SD; Mountain Plains Research (GRL), Bozeman, Mont; Virginia Commonwealth University (JB), (EB) Richmond; and Binghamton University (MNS), Binghamton, NY

Correspondence: Reprint requests should be addressed to Thomas K. Welty, MD, 5950 East Jeremy Lane, Flagstaff, AZ 86004

	Abstract

Top Notes Abstract Methods Results Discussion References

 
Background: Health care providers can more effectively prevent fetal alcohol syndrome and prenatal alcohol exposure if they know more about mothers who have children with fetal alcohol syndrome (FAS) or some characteristics of FAS.

Methods: We conducted two retrospective case-control studies of Northern Plains Indian children with FAS and some characteristics of FAS diagnosed from 1981 to 1993 by using the International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM), code 760.71. We compared mothers who had children with FAS or some characteristics of FAS with mothers who had children that did not have FAS.

Results: Compared with control mothers, 43 mothers who had children with FAS and 35 mothers who had children with some characteristics of FAS were older, had fewer prenatal visits, more pregnancies, more mental health problems, and more injuries (both total and alcohol-related). Although the prevalence of drinking was high in both case and control mothers, case mothers had more alcohol-related medical problems, drank heavily, in binges, and daily more often than control mothers.

Conclusions: Women with injuries and mental health problems should be screened for substance use. Mothers of children with FAS or of some characteristics of FAS have numerous needs that must be addressed to prevent future prenatal alcohol exposure.

	Methods

Top Notes Abstract Methods Results Discussion References

 
The protocol was reviewed and approved by the Aberdeen Area Indian Health Service (IHS), and the national IHS Institutional Review Boards, and four Northern Plains tribes. At four Northern Plains IHS hospitals or clinics, FAS or some characteristics of FAS were diagnosed in children from 1981 to 1993 by using the International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM), code 760.71.⁵ This code includes noxious influences (specifically alcohol) affecting the fetus or newborn through placenta or breast milk and includes FAS.

FAS cases were defined as children who met all five of the following criteria, based on documentation in their medical records: (1) prenatal alcohol exposure or maternal history of alcohol consumption, (2) FAS diagnosed or noted as a suspected diagnosis by a physician, (3) one or more facial features characteristic of FAS, (4) growth deficiency (height or weight 10th percentile for age), and (5) central nervous system impairment.⁶ If children met only one to four of these criteria, they were defined as cases having some characteristics of FAS.

Of 142 medical records in the four communities that had an ICD-9 code of 760.71, 43 (30%) met 5 FAS case criteria. Of the remaining 99 medical records, 35 that met one to four FAS case criteria were randomly selected. Thus, we report two separate analyses of data: one based on 43 case mothers whose children had FAS compared with 86 control mothers (study 1), and the second based on 35 case mothers whose children had one to four characteristics of FAS compared with 70 different control mothers (study 2). The methods used for both studies were identical. For each case mother, we selected two control mothers from the same community: one who gave birth immediately before the birth of the child with FAS or the child with some characteristics of FAS, and one who gave birth immediately after. If the control child had FAS, the next nearest child born was selected instead.

For inclusion into the studies, medical records of the mother and child for both cases and controls had to be available for abstraction. When available, medical records of the following family members were also abstracted for both cases and controls: father of the index child, maternal grandmother, next older sibling, and next younger sibling.

Maternal alcohol abuse was defined when one or more of the following patterns of drinking were recorded in the maternal medical record: (1) heavy, which included terms "heavy," "intoxicated," "alcohol abuse," "drunk," and "alcoholism;" (2) binge drinking of five or more drinks per occasion or blood alcohol levels higher than 200 mg/dL; or (3) daily alcohol use.

We reviewed the entire lifetime maternal medical record (hospital, emergency department, and outpatient) for documentation of sexual abuse, suicide attempts, depression, cirrhosis, delirium tremens, and maternal cognitive function. For aerosol use, sexually transmitted diseases, injuries (intentional and unintentional), smoking, and alcohol abuse, we limited our review to five years before the birth of the case or control child until 1 August 1995. We used data abstracted from those reviews to calculate and compare rates of these problems in case and control mothers. We defined maternal cognitive dysfunction as cognitive problems that differed from those caused by adult alcohol abuse but that are typical of adults who are affected by fetal alcohol exposure themselves (poor judgment, poor memory, slow learning, and lack of abstract thinking skills).

The primary author provided orientation for all abstractors and regularly monitored their work. Two abstractors reviewed the same medical records of 10% of the cases and controls. If there was less than 90% concurrence, the charts were abstracted again. There was 91.5% concurrence in double abstraction of 31 medical records. We double entered all data and corrected all discrepancies.

A matched analysis was done using corrected McNemar chi-square and correlated t tests to determine statistical significance of differences in categorical and continuous variables.^7,8 Using chi-square and t tests to determine statistical significance, we analyzed unmatched case and control mothers who went to alcohol treatment or attempted suicide to compare relapse rates and numbers of suicide attempts. Fisher’s exact test was used for discrete variables when there were fewer than five expected observations in one or more cells of a 2 x 2 table. P values of .05 or less were considered to be statistically significant. We calculated odds ratios (OR) using maximum likelihood estimates and exact 95% confidence interval to assess the strength of associations. We used logistic regression to verify results controlling for age and to look for the best predictors for having a child with FAS.

	Results

Top Notes Abstract Methods Results Discussion References

 
By definition, children of case mothers in study 1 had all five FAS criteria, and children of case mothers in study 2 case had an average of 3.2 FAS criteria. On average case mothers from both studies started prenatal care during the sixth month of pregnancy, compared with control mothers, case mothers had significantly fewer prenatal visits, had more pregnancies, had more children before the index child, and were older (Table 1). Three case mothers in study 1 and one case mother in study 2 had died; none of the control mothers in either study had died.

About 80% of case mothers in study 1 and 60% of case mothers in study 2 had alcohol-related medical problems. Trauma, delirium tremens, and alcohol abuse were reported significantly more frequently for case mothers than control mothers of both studies (Table 4). Nine case mothers in study 1 (23.0%) and 6 case mothers in study 2 (15.4%) had all three categories of alcohol abuse (heavy, binge, and daily) recorded in their medical records, whereas none of the control mothers in study 1 and only one mother in study 2 had all three recorded (P < .05 for both differences).

Because of their high alcohol content, aerosols, including Lysol and hairspray, are sometimes consumed as a beverage by persons with severe chemical dependency. In this study, none of the control mothers abused aerosols compared with 7.0% of case mothers in study 1 and 2.9% of case mothers in study 2 (Table 4). Smoking rates were high in case and control mothers in both studies and did not differ.

Case mothers from both studies had significantly higher rates of cognitive dysfunction typical of adults with FAS than did control mothers (Table 4). Alcohol use was documented significantly more often in the records of maternal grandmothers of case children in both studies compared with the records of grandmothers of control children. More than 50% of case and control fathers in both studies had alcohol use documented in their medical records.

Logistic regression analyses did not change the significance of the associations reported. Maternal drinking, maternal age, intentional injuries, depression, and sexual abuse were the strongest predictors of FAS. The only significant differences between case mothers in study 1 and study 2 are noted in Table 4 and suggest that mothers of children of FAS had significantly higher levels of alcohol consumption and a more serious alcohol addiction than mothers of children who had some characteristics of FAS.

	Discussion

Top Notes Abstract Methods Results Discussion References

 
Because of difficulties in defining "some characteristics of FAS," research has been limited for mothers whose children do not have all the criteria for FAS. In the past fetal alcohol effects was used as a diagnosis in these children; now the terms alcohol-related neurodevelopmental disorder and alcohol-related birth defects are used.⁹ These two studies of mothers of children who had FAS and some characteristics of FAS provide a unique opportunity to learn more about each group of women and to make comparisons between them. Case mothers from both studies had similar demographic characteristics and rates of injuries, but mothers of children with FAS (study 1) had significantly higher rates of alcohol abuse and referral for alcohol treatment than mothers with children with some characteristics of FAS (study 2). Thus, children of mothers in study 1 might have had greater prenatal alcohol exposure that caused them to have all five characteristics of FAS.

The mean age for mothers in study 1 was 26.6 years and for mothers in study 2 was 28.0 years compared with mean maternal ages of 26.7, 27.4, 29.0, 29.7 and 29.9 years in four studies of mothers of children with FAS.^10–14 In fact, the first modern published report of advanced maternal age as a risk factor for FAS was also conducted among American Indians.¹⁴ Another study found that pregnant women older than 35 years had the highest prevalence of prenatal drinking (21.9%) of any age-group.¹⁵

Occurrence of FAS at a young maternal age in our study suggests an early age of onset of alcohol abuse, possibly related to high rates of alcohol use among maternal grandmothers. Women who abuse alcohol receive less support from their families and friends than do women who do not abuse alcohol.¹⁶ Younger women tend to drink in a heavy, episodic pattern.^4,17 Because heavy alcohol use has a stronger association with FAS than moderate drinking,¹⁸ this heavy-binging pattern is likely to have more adverse effects on the fetus than consumption of smaller quantities of alcohol per occasion.¹⁹ In addition to binge drinking, case mothers in study 1 and study 2 were 49 and 20 times, respectively, more likely than control mothers to drink alcohol on a daily basis.

Gravidity and parity for case and control mothers in both studies were greater than reported for urban Northern Plains Indian prenatal patients.⁴ Mothers who have children with FAS or some characteristics of FAS should be strongly encouraged to postpone pregnancies until they are able to abstain from alcohol use. Case and control mothers from both studies had similar rates of family planning usage, but a higher proportion of case mothers in study 1 chose sterilization. In some cases, however, sterilization was not readily available, and mothers often requested sterilization more than once before the procedure was completed. Case mothers in study 2 were less likely than control mothers to use birth control pills. Accessibility to all forms of family planning needs to be a priority.

The mean educational level of case mothers in study 1 (9.8 years) was significantly lower than that for control mothers (11.0 years), compared with a mean maternal educational level of 10.6 years for mothers of children with FAS in North Dakota.¹³ A study in Alaska found 41% of case mothers had not graduated from high school.¹² Lower educational level has been associated with an earlier age of first drinking and with heavier alcohol use in American Indians.²⁰ Educational materials need to be written at an appropriate reading level.

More then 60% of case and control mothers from both studies lived with partners who also drank alcohol, a pattern consistent with findings of other studies.^4,10,17 Cohabitation with partners who drink alcohol is strongly associated with women’s drinking.^10,17

Women who use alcohol experience more physical and sexual abuse than women who do not drink alcohol.¹⁶ Women who experience such abuse are also more likely to have mental health problems.^16,21 Problem drinking among women is linked to depression,²² and suicide occurs more frequently among young women who drink alcohol than among women who abstain from alcohol.²³

Unintentional injuries were significantly more common among case mothers than among control mothers in study 1. Previous studies have shown that serious trauma is often associated with alcohol use.^24,25 Intervening when women seek care for injuries related to alcohol use might prevent prenatal alcohol use as well as further injuries.

Case mothers from both studies had more medical problems related to their alcohol use than control mothers. In contrast with men, women who experience liver malfunction as a result of alcohol abuse might not recover when they quit drinking or cut down on their alcohol use.²⁶ Despite their many problems, case mothers had only about one half the number of prenatal visits as control mothers, suggesting the need for active follow-up of prenatal patients when they miss their appointments.

Mothers of children with FAS are at greater risk for having more children with FAS. If mothers continue to drink with successive pregnancies, children born later often have more profound effects of FAS.⁹ To prevent this repetitive, worsening damage to subsequent children, all mothers of children with FAS and some characteristics of FAS should be referred to treatment for their alcohol abuse. Referrals to treatment occurred more frequently for case mothers than for control mothers in both studies, likely as a result of the severity of alcohol abuse in case mothers. To prevent FAS and other alcohol-related effects, it is essential to counsel women of child-bearing age preconceptually to avoid substance use during pregnancy and to advise residential treatment for women who continue to abuse alcohol.

Because of the immense difficulty of overcoming chemical abuse and dependency, treatment relapses are common regardless of type and duration of current treatment modalities.²⁸ In our study, relapses after the first treatment occurred more often for case mothers than for control mothers who were referred to treatment in both studies. Alcohol use after the last treatment program decreased for both case and control mothers, showing that repetitive treatments are useful.

Women in treatment are often found to abuse other drugs as well.²³ Although use of aerosols as a beverage has been described,²⁹ use in pregnancy has not been reported. Women who drink products containing alcohol that are not beverages are likely so dependent on alcohol that they will drink any available liquid with a high alcohol content. Such potentially toxic products (eg, Lysol and hairspray) are readily available, and their consumption should be strongly discouraged. Smoking rates were similar for case and control mothers ( 60%), indicating need for universal smoking-cessation programs for prenatal patients in this population.

More than 60% of case and control mothers from both studies had a history of sexually transmitted diseases. This finding suggests need for further education on prevention, for more rigorous case finding and treatment, and for counseling and testing for human immunodeficiency virus infection.

Most case grandmothers in study 1 and 2 (93% and 79%, respectively) had alcohol use documented in their medical records compared with less than one half of control grandmothers. Although documentation of alcohol use during pregnancy was limited in the grandmothers’ charts, there were indications that nearly one third of case mothers themselves had cognitive dysfunction suggestive of adult FAS. Similar familial patterns of heavy drinking reported in a study of FAS in South Africa¹⁰ raise questions of whether fetal susceptibility to alcohol has a genetic basis, or whether it simply relates to familial patterns of alcohol abuse that are environmentally determined.

There are several limitations to these studies. The small numbers of case mothers in both studies limited the power of both studies to detect differences. Although the IHS unified medical record, which includes inpatient, outpatient, and emergency department records, enabled us to link risk factors and outcomes for most case and control mothers, the studies were limited by the inability to interview mothers or examine children. One important variable we could not fully evaluate was the cause of maternal cognitive dysfunction. Was it a result of fetal alcohol exposure or was it due to other causes? Ascertaining the cause of such cognitive problems would be speculative, however, even if mothers had been interviewed, because there is no definitive diagnostic test to determine the cause. As in any study using solely medical records, incomplete or inaccurate recording of data could have led to underreporting in records of both case and control mothers.

In conclusion, health care providers should routinely screen, promptly intervene, and refer for treatment all women of childbearing age who have problems associated with substance abuse, such as depression, sexual abuse, and injuries. Intervention becomes even more important for women who have had a child with FAS or some characteristics of FAS. Emergency departments and clinics should use standardized screening tools to assess such patients and should have protocols for referral to appropriate treatment facilities and for prenatal care. Prenatal care providers, especially, should use systematic screening for maternal alcohol use early in routine prenatal care and should work in concert with treatment programs geared toward pregnant women and their families. The IHS and Centers for Disease Control and Prevention have validated and approved a prenatal health assessment tool to screen for substance use in prenatal clinics.^30–32 The latest version of this form and instructions for its use are available on-line at http://forms.psc.gov/forms/IHS/ihs.html.

Health care providers should promote and assure ready access to effective family planning measures, especially for women who are unable to abstain from alcohol during pregnancy. More research and funding are urgently needed to determine which treatment modalities are most effective and to assure that appropriate treatment programs and facilities are readily available for substance abuse, mothers with special needs, such as cognitive mental illness, dysfunction, low educational level, pregnancy, dysfunctional families, and sole responsibility for child care. Greater efforts are needed to update physicians who provide emergency and prenatal care on effective methods for screening and counseling women for alcohol abuse.³³

	Acknowledgments

 
The authors gratefully acknowledge the record abstraction done by Angel Wilson, FNP; Mary Ewing, FNP; George Coy, MPH; Barbara Frost, MD; Betty Reppert, PA-C, MPH; Patricia Reams, MD, MPH; Dana Sleicher, MA, MPH; Patricia Maddox, MSN, MPH; Joan Kub, PhD; Juliette Raymond, MD, MPH; Barbara E. Parker, RN, MPH; Nancy Glass, MSN, MPH; Luis Callejas, MD, MPH; Elizabeth Jordan, RN, MSN; Nancy Deckert, RN; Deborah Kuehn, RN/CNP, MSN; L Russell Canfield, MD; and Katherine Canfield, MD. The authors also gratefully acknowledge the data entry done by Andrew Desruisseau, MD, John M. Marion, Laurie Pope, and Loralei Lacina, MD. Michele Strachan, MD, Don Blackman, PhD, Eva Marie Smith, MD, R. Louise Floyd, DSN, Diane Burkom, and the late Christopher Krogh, MD, made valuable contributions to the project. Edith Welty, MD, and Phil May, PhD, provided editorial input.

	Notes

Top Notes Abstract Methods Results Discussion References

 
This study was supported through a memorandum of agreement between the Indian Health Service and the Centers for Disease Control and Prevention. The opinions expressed in this article are those of the authors and do not necessarily reflect those of the Indian Health Service.

Received for publication February 11, 2003. Revision received February 11, 2003.

	References

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