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Hirschsprung's disease

Hirschsprung's disease, or 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. more...

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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.

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.

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PEG 3350 vs. lactulose for constipation in children
From American Family Physician, 5/15/05 by Mark Ebele

Clinical Question: Is polyethylene glycol (PEG) 3350 or lactulose a better treatment for children with functional constipation?

Setting: Outpatient (specialty)

Study Design: Randomized controlled trial (double-blinded)

Allocation: Concealed

Synopsis: In this study, investigators compared two osmotic laxatives, lactulose and PEG 3350, in children six months to 15 years of age who met two of the following four criteria: (1) fewer than three bowel movements per week; (2) encopresis more than once a week; (3) large amounts of stool (enough to clog the toilet) every one to four weeks; and (4) palpable abdominal or rectal mass. Children with an organic cause for constipation, such as Hirschsprung's disease, were excluded.

Before randomization, all children underwent an untreated one-week run-in period, during which symptoms were recorded and use of oral laxatives was not allowed. They received one enema per day for three days at the end of the week to clear any stool in the rectum. Children six months to six years of age were randomly assigned to receive 6 g of lactulose or 2.95 g of PEG 3350 per day; children six to 15 years of age received 12 g of lactulose or 5.9 g of PEG 3350 per day. After one week, treatment effect was assessed. The dosage was increased by one dose per day if symptoms persisted or was cut in half if the child was having diarrhea. A stimulant laxative also was given if the symptoms had not improved from baseline.

Patients were evaluated again at two, four, and eight weeks, at which time the dosage could be adjusted. The primary outcome, evaluated using per-protocol analysis, was treatment success at eight weeks, defined as at least three bowel movements per week and encopresis no more than once every two weeks. Although per-protocol analysis is less robust than intention-to-treat analysis, in this case only four of 50 patients in the PEG 3350 group and five of 50 patients in the lactulose group withdrew prematurely, making bias unlikely.

At the end of the eight-week study, the frequency of stools increased similarly in both groups from fewer than three to approximately seven per week. The frequency of encopresis decreased from more than once per day at intake to approximately three times per week in both groups. The end point of treatment success was achieved more often in the PEG 3350 group (56 versus 29 percent; P = .02; number needed to treat = four). Treatment was successful more often in girls, in children with less than one year of symptoms before enrollment, and in those with less encopresis at enrollment. PEG 3350 was somewhat better tolerated than lactulose in regard to side effects such as abdominal pain, pain at defecation, and straining at defecation, but children disliked the taste of PEG 3350 more than the taste of lactulose.

Bottom Line: PEG 3350 and lactulose increase stool frequency and decrease encopresis in children with functional constipation. Overall treatment success (using a somewhat arbitrary measure defined by the researchers) was more likely in the PEG 3350 group and, other than its taste, PEG 3350 was somewhat better tolerated than lactulose. (Level of Evidence: lb)

Study Reference: Voskuijl W, et al. PEG 3350 (Transipeg) versus lactulose in the treatment of childhood functional constipation: a double blind, randomised, controlled, multicentre trial. Gut November 2004;53:1590-4.

Used with permission from Ebell M. PEG 3350 better than lactulose for functional constipation in kids. Accessed online March 1, 2005, at: http://www.lnfoPOEMs.com.

COPYRIGHT 2005 American Academy of Family Physicians
COPYRIGHT 2005 Gale Group

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