Genetic Counseling in Congenital Heart Defects

Published on 07/06/2015 by admin

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33 Genetic Counseling in Congenital Heart Defects

David Chitayat

I. INTRODUCTION

A. Incidence

1. Cardiac abnormalities are among the most common defects.

2. Incidence is 1% among live-born babies.

3. Incidence is much higher in cases diagnosed prenatally.

B. Counseling for congenital heart diseases

1. Steps in counseling.

a. Obtain a family history and pregnancy history.

b. Discuss the fetal ultrasound findings.

c. Explain the prognosis.

d. Discuss the options available.

2. Throughout this process, the family should be made to feel secure that they will be supported by the health care professionals involved in their care, regardless of any decision they make.

II. THE PROCESS OF COUNSELING

A. Obtaining a family history

1. A three-generation family history should be obtained that contains critical medical data and biological relationships.

2. The risk is much greater if it is the mother rather than the father who has the heart defect.

3. Information regarding family members with congenital abnormalities, recurrent miscarriages, stillbirths, mental retardation, inherited conditions, and consanguinity should be recorded.

4. The family pedigree is a tool for:

a. Making a medical diagnosis.

b. Deciding on testing strategies.

c. Establishing the pattern of inheritance.

d. Identifying at-risk family members.

e. Calculating risks.

f. Determining reproductive options.

g. Distinguishing genetic from other risk factors.

h. Making decisions on medical management and surveillance.

i. Developing patient rapport.

j. Educating the patient and exploring the patient’s understanding.

B. Obtaining a pregnancy history

The pregnancy history should include information regarding maternal diseases such as diabetes mellitus and exposure to teratogens.

C. Discussing the cardiac abnormalities

1. The cardiac abnormalities should be discussed in the context of the other abnormalities detected in the fetus or newborn. For example, the cardiac abnormality may be minor, and yet the overall prognosis can be grim because of major brain abnormalities.

2. In cases with isolated cardiac abnormality or when the extracardiac abnormalities are minimal, the information regarding the prognosis and the surgical procedures should be provided mainly by the cardiologist.

3. When multiple abnormalities are detected or a specific condition is detected, the counseling should be given by a multidisciplinary group that includes everyone involved in the child’s care.

D. Providing support

1. The diagnosis of a fetal or newborn cardiac abnormality can be a time of crisis for the family.

2. The crisis can be exacerbated by not being able to secure an accurate diagnosis or by the unpredictability of the findings and prognosis.

3. This crisis can lead to a feeling of loss of control for the family.

4. Providers of genetic counseling should bear this in mind, and the session should be tailored to support the personal interests, beliefs, and coping mechanisms of the family.

III. ETIOLOGIC CATEGORIES IN CONGENITAL HEART DISEASES

A. Incidence

1. The majority of isolated cardiac abnormalities are multifactorial (85%).

2. Chromosome abnormalities are associated with 8% to 10%.

3. Single-gene disorders are found in 3% to 5% (Table 33-1).

TABLE 33-1 ETIOLOGIC DISTRIBUTION OF CONGENITAL HEART DISEASE

Etiology Percentage
Multifactorial 85%
Chromosome abnormalities 8–10%
Single gene disorders 3–5%
Maternal disease (IDDM, PKU, SLE etc.) 1%
Maternal exposures (infections, teratogens etc.) 1%

B. Mode of inheritance

1. Multifactorial inheritance (Fig. 33-1).

a. Multifactorial inheritance is the result of interactions of many genes (genes on different chromosomes and involved in a certain function) and environmental factors.

b. The sum of the genetic and environmental contribution determines the person’s liability to develop a disorder.

c. This liability has a bell-shaped curve in the general population, where most of the population is in the mean and unaffected, and a small portion of the population past the threshold and expresses the clinical manifestations.

d. This mode of inheritance is the most common cause of genetic disorders and is responsible for the greatest number of patients who will need special care or hospitalization because of genetic diseases, including congenital heart disease.

e. Up to 10% of newborn children express a multifactorial disease at some time in their lives, such as atopic reactions, diabetes, cancer, spina bifida, anencephaly, pyloric stenosis, cleft lip, cleft palate, congenital hip dysplasia, club foot, and congenital heart disease, among others. Some of these diseases occur more frequently in female patients (scoliosis, congenital dislocation of the hips) and some are more common in male patients (pyloric stenosis).

f. Hallmarks for multifactorial inheritance.

    (1) Most affected children have normal parents. This is true of diseases with quantitative traits.
    (2) Recurrence risk increases with the number of affected children in a family.
    (3) Recurrence risk increases with the severity of the defect. A more severely affected parent is more likely to produce an affected child.
    (4) Consanguinity slightly increases the risk of having an affected child.
    (5) The risk of affected relatives falls off very quickly with the degree of relationship. Thus, the recurrence risk for a second-degree relative is about half of that of a first-degree relative, and the risk for a third-degree relative is about the same as for the general population.
    (6) If the two sexes have a different probability of being affected, the less likely sex, if affected, is the more likely to produce an affected offspring.
    (7) If the population frequency is P, the risk for first-degree relatives is image. Thus, the lower the incidence of a condition in the population, the greater the relative increased risk for siblings (e.g., cleft lip). Environmental factors as well as genetic factors are involved.

g. Empirical risk for some congenital cardiac abnormalities is outlined in Table 33-2.

2. Chromosome abnormalities.

a. Chromosome abnormalities are detected in about 10% of newborns with congenital heart disease (Ferencz et al, 1989).

b. The incidence in fetuses with prenatally diagnosed congenital heart disease is most probably threefold higher (Berg et al, 1988).

c. Because specific congenital heart diseases are known to be associated with certain chromosome abnormalities, we can assume that the gene or genes associated with these abnormalities must have a major role in cardiac development (Table 33-3).

d. This is emphasized in contiguous-gene disorders where a specific gene known to have a major role in the development of the heart is deleted and results in specific cardiac abnormalities (Table 33-4).

3. Single-gene disorders.

a. Autosomal recessive inheritance and conditions.

    (1) Autosomal recessive conditions occur when a person inherits two mutated alleles, one from each parent.
    (2) The unaffected parent, who carries only a single copy of the mutated gene, is a carrier, or heterozygote, and unaffected.
    (3) The affected person who inherited the abnormal copy of the gene from each parent is:
       (a) A homozygote when the mutation inherited from each of the parents is the same.
       (b) A compound heterozygote when each of the parents contributed a gene with a different mutation.
    (4) Once a homozygote is identified, the recurrence risk for his or her parents is 25%.
    (5) Each of the unaffected siblings of a person with an autosomal recessive disorder has a two-thirds chance of being a heterozygote.
    (6) Because the likelihood is low that any two persons selected randomly will be heterozygous for the same mutant allele, the condition affects one generation.
    (7) This pattern of inheritance is called horizontal.
    (8) Consanguinity can lead to an increased likelihood of mating between heterozygotes and thus increased incidence of the condition.
    (9) Relatively common congenital heart diseases with autosomal recessive inheritance are listed in Table 33-5.

b. Autosomal dominant inheritance and conditions.

    (1) A dominantly inherited condition is detectable in a person who has only one altered gene of a pair. Such a person is called a heterozygote.
    (2) Having only a single mutated copy of the gene is sufficient to develop a recognizable clinical phenotype, and the transmission pattern of autosomal dominant conditions is called vertical because it passes from one generation to the next.
    (3) Thus, the chance that any individual germ cell contains the chromosome with the mutated gene is 50%, and the chance for an affected person to transmit the abnormal gene is 50% with each conception.
    (4) Some of the cases are the result of a new mutation in the sperm or egg that originated the affected person.
    (5) Some of the new dominant mutations are associated with advanced paternal age (e.g., Marfan’s syndrome, Apert’s syndrome, achondroplasia).
    (6) Relatively common congenital heart diseases with autosomal dominant inheritance are listed in Table 33-6.
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