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Hirschsprung's disease, or congenital aganglionic megacolon, involves an enlargement of the colon, caused by bowel obstruction resulting from an aganglionic section of bowel (the normal enteric nerves are absent) that starts at the anus and progresses upwards. The length of bowel that is affected varies but seldom stretches for more than a foot or so.
History and Description
This disease is named for Harald Hirschsprung, the Danish physician who first described the disease in 1886, describing two infants who had died with swollen bellies. "The autopsies showed identical pictures with a pronounced dilatation and hypertrophy of the colon as the dominant features" (Madsen 17).
Hirschsprung’s disease is a congenital disorder of the colon in which certain nerve cells, known as ganglion cells, are absent, causing chronic constipation (Worman and Ganiats 487). The lack of ganglion cells, proven by Orvar Swenson to be the cause of the disease, disables the muscular peristalsis needed to move stool through the colon, thus creating a blockage. One in five thousand children suffer from Hirschsprung’s. Four times as many males get this disease than females. Hirschsprung’s develops in the fetus during the early stages of pregnancy. Typical symptoms for infants include not having their first bowel movement (meconium) within 48 hours of birth, and repeated vomiting. Some infants may have a swollen abdomen. Two thirds of the cases of Hirschsprung’s are diagnosed within three months of the birth. Occasionally symptoms do not appear until early adulthood. A barium enema is the mainstay of diagnosis of Hirschsprung’s, though a rectal biopsy showing the lack of ganglion cells is the only certain method of diagnosis.
The usual treatment is "pull-through" surgery where the portion of the colon that does have nerve cells is pulled through and sewn over the part that lacks nerve cells (National Digestive Diseases Information Clearinghouse). For a long time, Hirschsprung’s was considered a multi-factorial disorder, where a combination of nature and nurture were considered to be the cause (Madsen 19). However, in August of 1993, two articles by independent groups in Nature Genetics said that Hirschsprung’s disease could be mapped to a stretch of chromosome 10 (Angrist 351). This research also suggested that a single gene was responsible for the disorder. However, the researchers were unable to isolate the single gene that they thought caused Hirschsprung’s.
Genetic basis
In 2002, scientists thought they found the solution. According to this new research, the interaction of two variant genes caused Hirschsprung’s. RET was isolated as the gene on chromosome 10, and it was determined that it could have dominant mutations that cause loss of function (Passarge 11). An important gene that RET has to interact with in order for Hirschsprung’s to develop is EDNRB, which is on chromosome 13. Six other genes were discovered to be associated with Hirschsprung’s. According to the study, these genes are GDNF on chromosome 5, EDN3 on chromosome 20, SOX10 on chromosome 22, ECE1 on chromosome 1, NTN on chromosome 19, and SIP1 on chromosome 2. These scientists concluded that the mode of inheritance for Hirschsprung’s is oligogenic inheritance (Passarge 11). This means that two mutated genes interact to cause a disorder. Variations in RET and EDNRB have to coexist in order for a child to get Hirschsprung’s. However, although six other genes were shown to have an effect on Hirschsprung’s, the researchers were unable to determine how they interacted with RET and EDNRB. Thus, the specifics of the origins of the disease are still not completely known.
RET codes for proteins that help the neural crest cells (which become ganglion cells) move through the digestive tract during the development of the embryo (Sawin). EDNRB codes for proteins to actually connect these nerve cells to the digestive tract. This means that the absence of certain nerve fibers in the colon could be directly related to these two genes mutating so the wrong proteins are produced. Research published in June of 2004 suggests that there are actually ten genes associated with Hirschsprung’s disease (Puri and Shinkai). Also, new research suggests that mutations in genomic sequences involved in regulating EDNRB have a bigger impact on Hirschsprung’s disease than previously thought.
Dr. Bob Sawin of Seattle’s Children's Hospital notes that it is generally accepted in the scientific community that the gene RET is the most important gene when looking for the genetic cause of Hirschsprung’s disease. RET can mutate in many ways, and is associated with Down syndrome. Since Down Syndrome occurs in two percent of Hirschsprung’s cases, there is a likelihood that RET is involved heavily in both Hirschprung's disease and Down Syndrome. RET is also associated with thyroid cancer and neuroblastoma (Sawin). Both of these disorders have also been observed in Hirschsprung’s patients with greater frequency than in the general population. One function that RET controls is the travel of the neural crest cells through the intestines in the developing fetus. When RET mutations cause Hirschsprung’s disease, “the cells start traveling through the colon, only to be stopped once the mutation occurs” (Sawin). The earlier the mutation of RET occurs in Hirschsprung’s disease, the more severe the disorder becomes (Sawin).
While researchers remain uncertain of the exact genetic cause of Hirschsprung’s disease, Dr. Sawin notes that in familial cases, (in which families have multiple affected patients) Hirschsprung’s disease exhibits autosomal dominant transmission, with the gene RET being dominant. However, in sporadic cases, Sawin notes that there has been no inheritance pattern identified. While scientists remain convinced that Hirschsprung’s disease is genetic, the exact cause remains a mystery.
Treating Hirschsprung’s is much easier than determining the genetic causes of this disorder. The only way to treat Hirschsprung’s disease is through surgery (National Digestive Diseases Information Clearinghouse). If Hirschsprung’s goes untreated, the patient can develop enterocolitis, the inflammation of the small intestine and the colon (Sawin). This was the cause of death of the two boys that Harald Hirschsprung observed. Surgery is now used to remove the non-functioning portion of the bowel in order to restore bowel function (Sawin).
Surgical treatment
There used to be two steps typically used to achieve this goal. The first stage used to be a colostomy. When a colostomy is performed, the large intestine is cut and an opening is made through the abdomen. This allows bowel contents to be discharged into a bag. Later, when the child’s weight, age, and condition is right, a pull-through procedure is performed. Orvar Swenson, the same man who discovered the cause of Hirschsprung’s, first performed it in 1948 (Swenson 839). The pull-through procedure repairs the colon by connecting the functioning portion of the bowel to the anus. The pull through procedure is the typical method for treating Hirschsprung’s in younger patients. Swenson devised the original procedure, but the pull-through surgery has been modified many times. Sawin, an expert in pull-through surgery, notes that, "Although there are about five different pull-through procedures, they are all more or less equally effective in treating the disorder." The Swenson, Soave, Duhamel, and Boley procedures all vary slightly from each other with equivalent results (Sawin). The Swenson procedure leaves a small portion of the diseased bowel. The Soave procedure leaves the outer wall of the colon unaltered. The Boley procedure is just a small modification of the Soave procedure. Meanwhile, the Duhamel procedure uses a surgical stapler to connect the good and bad bowel. The front of the bowel will end up with no cells, but the back will be healthy (Sawin). Sawin notes that “Pull-through procedures used to require a colostomy, but with increased awareness among doctors and parents about the symptoms of Hirschsprung’s and with early diagnosis, doctors can keep the colon clean and perform the pull-through procedure without a colostomy”. In general, “85 percent of patients that have the pull-through surgery live normal lives afterwards. The other 15 percent have to take a laxative for the rest of their lives”. In rare cases, if the mother has Hirschsprung’s and passes it on to her child, the child is said to have “total Hirschsprung’s”, where there are no ganglion cells at all in the colon (Sawin). In this case, the Martin pull-through operation is conducted. The Martin operation is the most invasive of the operations, for it requires a colostomy no matter how early you diagnose total Hirschsprung’s. Even rarer, notes Dr. Sawin, "there are times where the disease begins in the small intestine, making treatment even harder". A colostomy is conducted along with the Martin operation when a child has total Hirschsprung’s or small intestine Hirschsprung’s. On very rare occasions, pull-through surgery is not the preferred method when it comes to treating Hirschsprung’s disease.
If the affected portion of the lower intestine is restricted to the lower portion of the rectum, other surgical procedures, such as the posterior rectal myectomy, can be performed.
When suspicion of Hirschsprung's is high, and barium enema has been inconclusive, rectal biopsy can be used to definitively diagnose the disease.
See also
External links
- (RET gene, the "rearranged during transfection" protooncogene)
- (OMIM page on Hirschsprung's disease)
Eponymous diseases | Gastroenterology
Maladie de Hirschsprung | Ondine's vloek | Choroba Hirschsprunga | Morbus Hirschsprung
"Hirschsprung's disease"