Congenital disorders |
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MeSH |
D009358 |
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A congenital disorder, or congenital disease, is a condition existing at birth and often before birth, or that develops during the first month of life (neonatal disease), regardless of causation. Of these diseases, those characterized by structural deformities are termed "congenital anomalies" and involve defects in or damage to a developing fetus.
A congenital disorder may be the result of genetic abnormalities, the intrauterine (uterus) environment, errors of morphogenesis, infection, or a chromosomal abnormality. The outcome of the disorder will depend on complex interactions between the pre-natal deficit and the post-natal environment.[1] Animal studies indicate that the mother's (and possibly the father's) diet, vitamin intake, and glucose levels prior to ovulation and conception have long-term effects on fetal growth and adolescent and adult disease.[2] Congenital disorders vary widely in causation and abnormalities. Any substance that causes birth defects is known as a teratogen.
The older term congenital[3] disorder does not necessarily refer to a genetic disorder despite the similarity of the words. Some disorders can be detected before birth through prenatal diagnosis (screening).
Contents
- 1 Classification
- 1.1 Primarily structural
- 1.2 Other
- 2 Causes
- 3 Epidemiology
- 4 Occurrence rate
- 4.1 Relationship of congenital anomalies with sex
- 5 Fossil record
- 6 See also
- 7 References
- 8 External links
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Classification
Much of the language used for describing congenital conditions predates genomic mapping, and structural conditions are often considered separately from other congenital conditions. It is now known that many metabolic conditions may have subtle structural expression, and structural conditions often have genetic links. Still, congenital conditions are often classified in a structural basis, organized when possible by primary organ system affected.
Primarily structural
Main article: Congenital abnormality
Several terms are used to describe congenital abnormalities. (Some of these are also used to describe noncongenital conditions, and more than one term may apply in an individual condition.)
- A congenital physical anomaly is an abnormality of the structure of a body part. An anomaly may or may not be perceived as a problem condition. Many, if not most, people have one or more minor physical anomalies if examined carefully. Examples of minor anomalies can include curvature of the 5th finger (clinodactyly), a third nipple, tiny indentations of the skin near the ears (preauricular pits), shortness of the 4th metacarpal or metatarsal bones, or dimples over the lower spine (sacral dimples). Some minor anomalies may be clues to more significant internal abnormalities.
- Birth defect is a widely used term for a congenital malformation, i.e. a congenital, physical anomaly which is recognizable at birth, and which is significant enough to be considered a problem. According to the CDC, most birth defects are believed to be caused by a complex mix of factors including genetics, environment, and behaviors,[1] though many birth defects have no known cause. An example of a birth defect is cleft palate.
- A congenital malformation is a congenital physical anomaly that is deleterious, i.e. a structural defect perceived as a problem. A typical combination of malformations affecting more than one body part is referred to as a malformation syndrome.
- Some conditions are due to abnormal tissue development:
- A malformation is associated with a disorder of tissue development.[4] Malformations often occur in the first trimester.
- A dysplasia is a disorder at the organ level that is due to problems with tissue development.[4]
- It is also possible for conditions to arise after tissue is formed:
- A deformation is a condition arising from mechanical stress to normal tissue.[4] Deformations often occur in the second or third semester, and can be due to oligohydramnios.
- A disruption involves breakdown of normal tissues.[4]
- When multiple effects occur in a specified order, it is known as a sequence. When the order is not known, it is a syndrome.
Other
- Genetic disorders or diseases are all congenital, though they may not be expressed or recognized until later in life. Genetic diseases may be divided into single-gene defects, multiple-gene disorders, or chromosomal defects. Single-gene defects may arise from abnormalities of both copies of an autosomal gene (a recessive disorder) or of only one of the two copies (a dominant disorder). Some conditions result from deletions or abnormalities of a few genes located contiguously on a chromosome. Chromosomal disorders involve the loss or duplication of larger portions of a chromosome (or an entire chromosome) containing hundreds of genes. Large chromosomal abnormalities always produce effects on many different body parts and organ systems.
- A congenital metabolic disease is also referred to as an inborn error of metabolism. Most of these are single gene defects, usually heritable. Many affect the structure of body parts but some simply affect the function.
- Other well defined genetic conditions may affect the production of hormones, receptors, structural proteins, and ion channels.
Causes
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This section requires expansion. (January 2010) |
Antibiotics
Use of antibiotics around the time of conception, particularly sulfonamides and nitrofurantoin are associated with major birth defects. Whether or not this association is causal has not been determined.[5]
Epidemiology
Disability-adjusted life year for congenital anomalies per 100,000 inhabitants in 2004.[6]
no data
less than 160
160-240
240-320
320-400
400-480
480-560
560-640
640-720
720-800
800-900
900-950
more than 950
Cell division errors can be due to a lack of nutrients or availability of atomic building blocks, or the presence of toxins that impede normal growth. Division errors which occur very early in the development of a multicellular organism can result in large scale structural and functional differences in the organism's final shape. For example it is now understood that a lack of folic acid in the diet of a mother can cause cellular neural tube deformities that result in Spina Bifida.
External physical shocks or constrainment due to growth in a restricted space, may result in unintended deformation or separation of cellular structures resulting in an abnormal final shape or damaged structures unable to function as expected.
For multicellular organisms that develop in a womb, the physical interference or presence of other similarly developing organisms such as twins can result in the two cellular masses being integrated into a larger whole, with the combined cells attempting to continue to develop in a matter that satisfies the intended growth patterns of both cell masses. The two cellular masses can compete with each other, and may either duplicate or merge various structures. This results in conditions such as conjoined twins, and the resulting merged organism may die at birth when it must leave the life-sustaining environment of the womb and must attempt to sustain its biological processes independently.
Occurrence rate
Relationship of congenital anomalies with sex
Many studies have found that the frequency of occurrence of certain congenital malformations depends on the sex of the child (table).[7][8][9][10][11] For example pyloric stenosis more often occurs at boys, and congenital hip dislocation is 4–5 times more often at girls. Among children with one kidney, there are approximately twice as many boys, whereas among children with three kidneys there are approximately 2.5 times more girls. The same pattern is observed among infants with excessive number of ribs, vertebrae, teeth and other organs which in a process of evolution have undergone reduction—among them there are more girls. Contrary, among the infants with their scarcity, there are more boys. Anencephaly is approximately twice frequently occurs at girls.[12] The number of boys born with 6 fingers is two times higher than the number of girls.[13]
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The sex ratio of patients with congenital malformations
Congenital anomaly |
Sex ratio, ♂♂:♀♀ |
Defects with female predominance |
|
Congenital hip dislocation |
1 : 5.2;[14] 1 : 5;[15] 1 : 8;[11] 1 : 3.7[16] |
Cleft palate |
1 : 3[15] |
Anencephaly |
1 : 1.9;[14] 1 : 2[12] |
Craniocele |
1 : 1.8[14] |
Aplasia of lung |
1 : 1.51[14] |
Spinal herniation |
1 : 1.4[14] |
Diverticulum of the esophagus |
1 : 1.4[14] |
Stomach |
1 : 1.4[14] |
Neutral defects |
|
Hypoplasia of the tibia and femur |
1 : 1.2[14] |
Spina bifida |
1 : 1.2[16] |
Atresia of small intestine |
1 : 1[14] |
Microcefaly |
1.2 : 1[16] |
Esophageal atresia |
1.3 : 1;[14] 1.5 : 1[16] |
Hydrocephalus |
1.3 : 1[16] |
Defects with male predominance |
|
Diverticula of the colon |
1.5 : 1[14] |
Atresia of the rectum |
1.5 : 1;[14] 2 : 1[16] |
Unilateral renal agenesis |
2 : 1;[14] 2.1 : 1[16] |
Schistocystis |
2 : 1[14] |
Harelip |
2 : 1;[15] 1.47 : 1[16] |
Bilateral renal agenesis |
2.6 : 1[14] |
Congenital anomalies of the genitourinary system |
2.7 : 1[11] |
Pyloric stenosis, congenital |
5 : 1;[15] 5.4 : 1[11] |
Meckel's diverticulum |
More common in boys[14] |
Congenital megacolon |
More common in boys[14] |
All defects |
1.22 : 1;[17] 1.29 : 1[11] |
- Data[11] obtained on opposite-sex twins. ** — Data[16] were obtained in the period 1983-1994.
P. M. Rajewski and A. L. Sherman (1976) have analyzed the frequency of congenital anomalies in relation to the system of the organism. Prevalence of men was recorded for the anomalies of phylogenetically younger organs and systems.[14]
In respect of an etiology, sexual distinctions can be divided on appearing before and after differentiation of male's gonads in during embryonic development, which begins from eighteenth week. The testosterone level in male embryos thus raises considerably.[18] The subsequent hormonal and physiological distinctions of male and female embryos can explain some sexual differences in frequency of congenital defects. It is difficult to explain the observed differences in the frequency of birth defects between the sexes by the details of the reproductive functions or the influence of environmental and social factors.
Fossil record
Main article: Paleopathology
Evidence for congenital deformities found in the fossil record is studied by paleopathologists, specialists in ancient disease and injury. Fossils bearing evidence of congenital deformity are scientifically significant because they can help scientists infer the evolutionary history of life's developmental processes. For instance, because a Tyrannosaurus rex specimen has been discovered with a block vertebra, it means that vertebrae have been developing the same basic way since at least the most recent common ancestor of dinosaurs and mammals. Other notable fossil deformities include a hatchling specimen of the bird-like dinosaur, Troodon, the tip of whose jaw was twisted.[19] Another notably deformed fossil was a specimen of the choristodere Hyphalosaurus, which had two heads- the oldest known example of polycephaly.[20]
See also
- Congenital abnormality
- Malformative syndrome
- ICD-10 Chapter Q: Congenital malformations, deformations and chromosomal abnormalities
- List of congenital disorders
- List of ICD-9 codes 740-759: Congenital anomalies
- March of Dimes
- Mitochondrial disease
References
- ^ a b Birth Defects Research. Centers for Disease Control and Prevention.
- ^ Gregory W. Rutecki (2010). "Pre-Prenatal Care: A Primary Care Primer on the Future". ConsultantLive.com. http://www.consultantlive.com/display/article/10162/1532211. Retrieved 25 September 2010.
- ^ Webster's Dictionary. http://www.merriam-webster.com/dictionary/congenital.
- ^ a b c d Graham, John Whichello (2007). Smith's Recognizable Patterns of Human Deformation, 3rd Edition. Philadelphia: Saunders. pp. 3. ISBN 0-7216-1489-2.
- ^ Crider KS, Cleves MA, Reefhuis J, Berry RJ, Hobbs CA, Hu DJ (November 2009). "Antibacterial medication use during pregnancy and risk of birth defects: National Birth Defects Prevention Study". Arch Pediatr Adolesc Med 163 (11): 978–85. doi:10.1001/archpediatrics.2009.188. PMID 19884587.
- ^ "WHO Disease and injury country estimates". World Health Organization. 2009. http://www.who.int/healthinfo/global_burden_disease/estimates_country/en/index.html. Retrieved Nov. 11, 2009.
- ^ Gittelsohn A., Milham S. (1964) Statistical study of twins—methods. Am. J. Public Health Nations Health 54 p. 286–294.
- ^ Fernando J., Arena P., Smith D. W. (1978) Sex liability to single structural defects. Am. J. Dis. Child 132 p. 970 –972.
- ^ Lubinsky M. S. (1997) Classifying sex biased congenital anomalies. Am. J. Med. Genet. 69 p. 225–228.
- ^ Lary J. M., Paulozzi L. J. (2001) Sex differences in the prevalence of human birth defects: a population-based study. Teratology 64 p. 237–251.
- ^ a b c d e f Wei Cui, Chang-Xing Ma, Yiwei Tang, e. a. (2005) Sex Differences in Birth Defects: A Study of Opposite-Sex Twins. Birth Defects Research (Part A) 73 p. 876–880.
- ^ a b World Health Organization reports). “Congenital malformations”, Geneve, 1966, p. 128.
- ^ Darwin C. (1871) The descent of man and selection in relation to sex. London, John Murray, 1st ed.
- ^ a b c d e f g h i j k l m n o p q r Rajewski P. M., Sherman A. L. (1976) The importance of gender in the epidemiology of malignant tumors (systemic-evolutionary approach). In: Mathematical treatment of medical-biological information. M., Nauka, p. 170–181.
- ^ a b c d Montagu A. (1968) Natural Superiority of Women, The, Altamira Press, 1999.
- ^ a b c d e f g h i Riley M., Halliday J. (2002) Birth Defects in Victoria 1999-2000, Melbourne.
- ^ Shaw G.M., Carmichael S.L., Kaidarova Z., Harris J.A. (2003) Differential risks to males and females for congenital malformations among 2.5 million California births, 1989-1997. Birth Defects Res. A Clin. Mol. Teratol. 67(12) p. 953-958.
- ^ Reyes F.I., Boroditsky R.S., Winter J.S., Faiman C. (1974) Studies on human sexual development. II. Fetal and maternal serum gonadotropin and sex steroid concentrations. J. Clin. Endocrinol. Metab. 38 p. 612– 617.
- ^ Molnar, R. E., 2001, Theropod paleopathology: a literature survey: In: Mesozoic Vertebrate Life, edited by Tanke, D. H., and Carpenter, K., Indiana University Press, p. 337-363.
- ^ Ji Q., Wu, X.-C. and Cheng, Y.-N. (2010). "Cretaceous choristoderan reptiles gave birth to live young." Naturwissenschaften, 97(4): 423-428. doi:10.1007/s00114-010-0654-2
External links
- CDC’s National Center on Birth Defects and Developmental Disabilities
- Birth Defects- Types and Causes
Pathology: Medical conditions and ICD code
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(Disease / Disorder / Illness, Syndrome / Sequence, Symptom / Sign, Injury, etc.)
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(A/B, 001–139) |
Infectious disease/Infection: Bacterial disease (G+, G-) · Virus disease · Parasitic disease (Protozoan infection, Helminthiasis, Ectoparasitic infestation) · Mycosis · Zoonosis
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(C/D,
140–239 &
279–289) |
Cancer (C00–D48, 140–239)
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Tumor
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Myeloid hematologic (D50–D77, 280–289)
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Anemia · Coagulopathy
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Lymphoid immune (D80–D89, 279)
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Immunodeficiency · Immunoproliferative disorder · Hypersensitivity
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(E, 240–278) |
Endocrine disease · Nutrition disorder · Inborn error of metabolism
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(F, 290–319) |
Mental disorder
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(G, 320–359) |
Nervous system disease (CNS, PNS) · Neuromuscular disease
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(H, 360–389) |
Eye disease · Ear disease
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(I, 390–459) |
Cardiovascular disease (Heart disease, Vascular disease)
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(J, 460–519) |
Respiratory disease (Obstructive lung disease, Restrictive lung disease, Pneumonia)
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(K, 520–579) |
Stomatognathic disease (Tooth disease) · Digestive disease (Esophageal, Stomach, Enteropathy, Liver, Pancreatic)
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(L, 680–709) |
Skin disease · skin appendages (Nail disease, Hair disease, Sweat gland disease)
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(M, 710–739) |
Musculoskeletal disorders: Myopathy · Arthropathy · Osteochondropathy (Osteopathy, Chondropathy)
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(N, 580–629) |
Urologic disease (Nephropathy, Urinary bladder disease) · Male genital disease · Breast disease · Female genital disease
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(O, 630–679) |
Complications of pregnancy · Obstetric labor complication · Puerperal disorder
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(P, 760–779) |
Fetal disease
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(Q, 740–759) |
Congenital disorder (Congenital abnormality)
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(R, 780–799) |
Syndromes · Medical signs (Eponymous)
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(S/T, 800–999) |
Bone fracture · Joint dislocation · Sprain · Strain · Subluxation · Head injury · Chest trauma · Poisoning
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