[Methodological Evaluation of Microarray in the Detection of α-Thalassemia].

OBJECTIVE: To proceed the clinical evaluation of DNA microarray for thalassemia gene detection. METHODS: Peripheral blood samples of 166 thalassemia gene test subjects were collected and tested for thalassemia genes by microarray chip method and Gap-PCR method combined with PCR-reverse dot blot hybridization method according to double-blind control test. The specificity, sensitivity, positive predictive value, negative predictive value, and total coincidence rate of the microarray chip method were evaluated. When the two methods were inconsistent, multiplex ligation dependent probe amplification (MLPA) was used to verify the deletional α-thalassemia. RESULTS: Compared with Gap-PCR method, specificity, sensitivity, positive predictive value, negative predictive value, Youden index, and total coincidence rate of microarray chip method was 100% (70/70), 96.88% (93/96), 100% (93/93), 95.89% (70/73), 0.969, and 97.59% (162/166), respectively, while compared with PCR-reverse dot blot hybridization method was 100% (125/125), 100% (41/41), 100% (41/41), 100% (125/125), 1, and 100% (166/166), respectively. CONCLUSION: The microarray chip method for α-thalassemia gene detection shows the advantages of high specificity, sensitivity, and throughput.

[Application of DNA Microarray in Genetic Mutation Detection in Patients with Thalassemia].

OBJECTIVE: To perform dried blood spots thalassemia gene detection in patients with positive blood phenotypes by microarray technology, and evaluate its value in clinical detection. METHODS: DNA samples were extracted from dried blood spots of 410 patients. Microarray technology was used to detect 3 deletion and 3 non-deletion types of α-thalassemia and 19 ß-thalassemia point mutations which were common gene mutions in China. RESULTS: There were 357 positive cases in all the 410 tested samples with the positive rate 87.07%, among which 299 cases (72.93%) carried deletion or point mutations of α-thalassemia, 29 cases (7.07%) carried point mutations of ß-thalassemia and 29 cases (7.07%) carried gene mutations of complex αß-thalassemia syndrome. The mutations of α-thalassemia were involved with --SEA heterozygous deletion (177 cases, 59.2%), αCS heterozygote (60 cases, 20.07%) and several other genotypes. The common mutations of ß- thalassemia were involved with ßCD41-42 heterozygote (10 cases, 34.48%) and ßCD17 heterozygote (9 cases, 31.03%). The mutations of complex αß-thalassemia syndrome were mainly involved with --SEA/αα+ßCD17/ßN (7 cases, 24.14%), αCSα/αα + ßCD41-42/ßN (3 cases, 10.34%) and -α4.2/αα + ßCD17/ßN (3 cases, 10.34%). CONCLUSION: The most common genetic mutations are --SEA for α-thalassemia and CD41-42 for ß-thalassemia in Liuzhou, Guangxi Zhuang Autonomous Region. A and ß-thalassemia can be detected at the same time by microarray chip technology in a high throughput manner.

[Study of closed colony of Microtus fortis infected with Schistosoma japonicum].

OBJECTIVE: To understand the pathological changes of tissues and organs in Microtus fortis infected with Schistosoma japonicum for further insight into the biological dynamic variation and explore immune mechanisms of M. fortis against S. japonicum infection. METHODS: The healthy M. fortis and mouse were infected with cercariae of S. japonicum through abdominal skin. On the day 12, 20 and 40, the M. fortis and mouse were sacrificed by cervical dislocation and dissected. The liver and kidney slices of M. fortis and mouse of the different groups were prepared and stained with hematoxylin eosin stain (HE) by conventional techniques, respectively. RESULTS: We did not find obvious lesions on the internal organs of mouse 12 d and 20 d after the infection and the lesions of M. fortis 40 d after the infection. However, white nodules appeared on the liver, kidney and spleen of the M. fortis 12 d and 20 d after the infection, and there were a lot of S. japonicum worms on pathological sections of inflamed liver and kidney tissues, and the boundary between worms and normal organization was clear. There were no parasites on pathological section of liver and kidney of mouse 12 d and 20 d after the infection. CONCLUSION: Among M. fortis, there are severe immune responses and the immune responses have an individual difference 12 days after S. japonicum infection.