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Chapter 064. The Practice of Genetics in Clinical Medicine (Part 2)

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Population Screening Mass genetic screening programs require tests of high enough sensitivity and specificity to be cost-effective. An effective screening program should fulfill the following criteria: that the tested disorder is prevalent and serious; that it can be influenced presymptomatically through lifestyle changes, screening, or medications; and that identification of risk does not result in undue discrimination or harm. Screening individuals of Jewish descent for the autosomal recessive neurodegenerative disorder Tay-Sachs disease has resulted in a dramatic decline in the incidence of this syndrome in the United States. On the other hand, screening for sickle cell disease or trait...

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  1. Chapter 064. The Practice of Genetics in Clinical Medicine (Part 2) Population Screening Mass genetic screening programs require tests of high enough sensitivity and specificity to be cost-effective. An effective screening program should fulfill the following criteria: that the tested disorder is prevalent and serious; that it can be influenced presymptomatically through lifestyle changes, screening, or medications; and that identification of risk does not result in undue discrimination or harm. Screening individuals of Jewish descent for the autosomal recessive neurodegenerative disorder Tay-Sachs disease has resulted in a dramatic decline in the incidence of this syndrome in the United States. On the other hand, screening for sickle cell disease or trait in the African-American population has sometimes resulted in insurance and employment discrimination.
  2. Mass screening for complex genetic disorders can result in potential problems. For example, cystic fibrosis is most commonly associated with alterations in ∆F508. This variant accounts for 30–80% of mutant alleles depending on the ethnic group. Nevertheless, cystic fibrosis is associated with pronounced genetic heterogeneity with more than 1000 disease-related mutations. The American College of Medical Genetics recommends a panel of 23 alleles, including the ∆F508 allele, for routine diagnostic and carrier testing. Analysis for the less common cystic fibrosis–associated mutations would greatly impact the cost of testing without significantly influencing the effectiveness of mass screening. Nevertheless, the individual who carries one of the less common cystic fibrosis–associated alterations will not benefit if testing is limited to a routine panel. Occupational health screening programs hold promise but also raise concerns about employment discrimination. These concerns were brought to light in 2001 when it was discovered that a railroad company was testing its employees, without consent, for a rare genetic condition that results in susceptibility to carpal tunnel syndrome. The Equal Employment Opportunity Commission argued that the tests were unlawful under the Americans with Disabilities Act. The Family History
  3. When two or more first-degree relatives are affected with asthma, cardiovascular disease, type 2 diabetes, breast cancer, colon cancer, or melanoma, the relative risk ranges from two- to fivefold, underscoring the importance of family history for these prevalent disorders. Pending further advances in genetic testing, the key to assessing the inherited risk for common adult-onset diseases rests in the collection and interpretation of a detailed personal and family medical history in conjunction with a directed physical examination. For example, a history of multiple family members with early-onset coronary artery disease, glucose intolerance, and hypertension should suggest increased risk for genetic, and perhaps environmental, predisposition to metabolic syndrome (Chap. 236). Individual patients with this family history should be monitored for the possible development of hypertension, diabetes, and hyperlipidemia. They should be counseled about the importance of avoiding additional risk factors such as obesity and cigarette smoking. Family history should be recorded in the form of a pedigree. At a minimum, pedigrees should convey health-related data on all first-degree relatives and selected second-degree relatives, including grandparents. When pedigrees appear to suggest an inherited disease, they should be extended to include additional family members. The determination of risk for an asymptomatic individual will vary depending on the size of the pedigree, the number of unaffected relatives, and the types of diagnoses, as well as the ages of disease
  4. onset within the family. For example, a woman with two first-degree relatives with breast cancer is at greater risk for a Mendelian disorder if she has a total of three female first-degree relatives than if she has a total of ten female first-degree relatives. Additional variables that should be documented in the pedigree include the presence or absence of nonhereditary risk factors among those affected with diseases, and the finding of multiple diseases in an individual patient. For instance, a woman with a history of both colon cancer and endometrial cancer is at risk for hereditary nonpolyposis colon cancer (HNPCC) regardless of her family history. When assessing the personal and family history, the physician should be alert to a younger age of disease onset than is usually seen in the general population. A 30-year-old with acute myocardial infarction should be considered at risk for a hereditary trait, even if there is no family history of premature coronary artery disease (Chap. 235). The absence of the nonhereditary risk factors typically associated with a disease also raises the prospect of genetic causation. A personal or family history of deep-vein thrombosis, in the absence of known environmental or medical risk factors, suggests a hereditary thrombotic disorder (Chap. 111). The physical examination also may provide important clues about the risk for a specific inherited disorder. A patient presenting with xanthomas at a young age should prompt consideration of familial hypercholesterolemia. Some adult-onset disease-causing mutations are more prevalent in certain ethnic groups. For instance, >2% of the Ashkenazi population carry one of three specific
  5. mutations in the BRCA1 or BRCA2 genes. The prevalence of the factor V Leiden allele ranges from 3 to 7% in Caucasians but is much lower in Africans or Asians.
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