Improving diagnosis of adult-type hypolactasia in patients with abdominal complaints.

BACKGROUND: Adult-type hypolactasia is caused by genetic lactase non-persistence. It is the most common cause of lactose intolerance, which results in gastrointestinal symptoms after ingestion of dairy products. Currently, lactose intolerance is investigated by the hydrogen breath test (HBT), which is considered the preferred diagnostic test. Adult-type hypolactasia may also be diagnosed by genotyping. The single nucleotide polymorphism -13910C>T, which is located upstream of the lactase gene (LCT), is tightly associated with lactase persistence. Several other variants, mostly in non-European populations, can also lead to lactase persistence. This study investigated the accuracy of a modified, recently proposed algorithm which includes genotyping for the diagnosis of adult-type hypolactasia in a patient population with unexplained abdominal complaints. METHODS: In 126 patients with unexplained abdominal symptoms or who were suspected to have adult-type hypolactasia, LCT genotyping by melting curve analysis on a LightCycler was performed. Those patients with CC(-13910) genotype (indicating loss of lactase expression) were directly referred to a dietician for a lactose-free diet. Those identified as CT(-13910) or TT(-13910) genotype underwent a HBT. Those who tested positive for hydrogen were also referred to a dietician for a lactose-free diet. The response to diet modification was recorded. RESULTS: Genotype prevalences were: CC(-13910): 43 (34.1%); CT(-13910): 48 (38.1%); TT(-13910): 33 (26.2%); TG-13915: 2 (1.6%). Eleven of 48 (23%) patients with CT(-13910)-genotype and 1/33 (3%) patients with TT(-13910)-genotype had a positive hydrogen breath test. They all improved after a lactose-free diet. Four of 43 (9%) patients with CC(-13910)-genotype still had symptoms after a lactose-free diet. CONCLUSIONS: The results show that lactase-genotype testing can be used as a first step to diagnose lactose intolerance in a patient population with unexplained abdominal complaints. It accurately identifies the group of patients sensitive to lactose, those who need further breath testing and those in whom adult-type hypolactasia can be excluded with high probability without performing a HBT. This algorithm would save hydrogen breath testing in more than 50% of the patients who present with unexplained abdominal symptoms.

Recognition of impaired atomoxetine metabolism because of low CYP2D6 activity.

Ten out of 100 children treated for attention deficit hyperactivity disorder with standard doses of atomoxetine were selected by a neurologist for cytochrome P450 2D6 and cytochrome P450 2C19 genotyping, based on late response (>9 weeks) and adverse effects (gastrointestinal problems, sleeping disorders, malaise, inactivity, and mood instabilities). After genotyping, eight children were confirmed to have compromised cytochrome P450 2D6 activity because of at least one nonfunctional or less functional allele. Cytochrome P450 C19 is a minor pathway in atomoxetine metabolism and therefore of less importance. Tailored therapeutic advice was given to the neurologist. Four children with compromised cytochrome P450 2D6 activity responded better after decreasing their atomoxetine dose. The other four ceased treatment because of initial adverse effects. These cases indicate that compromised atomoxetine metabolism can be recognized, based on adverse effects and late response to atomoxetine. Physicians should be aware of the typical pattern of adverse effects and late response in atomoxetine treatment, possibly indicating compromised cytochrome P450 2D6 activity. Cytochrome P450 2D6 genotyping before atomoxetine treatment may be beneficial in preventing overdosing or early cessation. Further research is needed to establish the cost versus benefit ratio of prospective cytochrome P450 2D6 genotyping in atomoxetine treatment.

Genotyping of hemochromatosis-associated mutations in the HFE gene by PCR-RFLP and a novel reverse hybridization method.

Comparative analysis of the hemochromatosis-associated mutations C282Y, H63D and S65C in the HFE gene in 51 patients using three different methods is reported. One PCR-RFLP method was based on general primers, whereas another employed mutation-specific mismatched primers. The third method was a new PCR-based reverse hybridisation line probe assay (LiPA), comprising DNA amplification by general primers followed by a single step reverse hybridization to specific probes, immobilized on a nitrocellulose strip. Forty-eight (94%) of the 51 samples yielded identical results by all three methods. Three discrepant results were obtained, caused by polymorphisms in the primer binding region, resulting in no amplification at all or selective amplification, leading to misinterpretation of the HFE genotype by PCR-RFLP. The design of the assay and the stringency of the reaction conditions used are crucial to obtain a correct HFE genotype. PCR-LiPA offers an easy and reliable alternative to currently used conventional methods.