Objective The bone marrow mesenchymal stem cells (BMSCs) have the capacity to differentiate into insul in-producing cells (IPCs) in vitro. However, low differentiation efficiency and poor maturity are the main obstacles. To investigate the feasibil ity of BMSCs differentiation into IPCs in diabetic pancreatic microenvironment of pigs. Methods BMSCs were isolated and purified from the bone marrow of a 4-week-old male pig. Fifteen female pigs (aged 8 to 10 weeks, weighing 8 to 10 kg) were randomly divided into 3 groups: normal control group (group A, n=5), diabetic control group (group B, n=5), and BMSCs transplanted group (group C, n=5). The pigs of groups B and C were treated by auris vein injections of styeptozocin and alloxan for 3 days to induce diabetes mell itus (DM) model, whose blood glucose level 2 days all greater than 17 mmol/L was successful DM model. A total of 1.1 mL of the 3rd passage BMSCs labeled with enhanced green fluorescent protein (EGFP), with cell density of 5 × 107/ mL, were injected into subcapsular pancreas of group C at multi ple points, normal saline at the same dosage into those of groups A and B. After 30 days of monitoring blood glucose, the histological analysis of islet number and size were done; the immunofluorescence staining was used to detect the protein expression of insul in in the new-formed islets. The EGFP+ cells were collected from the sections using laser-capture microdissection; RT-PCR was used to detect insulin mRNA and pancreatic and duodenal homeobox factor 1 (PDX1) mRNA expressions from EGFP+ cells, and the insul in and sexdetermining region of the Y chromosome (SRY) genes were detected by fluorescence in situ hybridization (FISH). Results The blood glucose level decreased significantly in group C when compared with that in group B from 18 days and gradually decreased with time (P lt; 0.05). The histological observation showed that the number of islets was increased significantly in group C when compared with that in group B (10.9 ± 2.2 vs. 4.6 ± 1.4, P lt; 0.05), and there was no significant difference when compared with that in group A (10.9 ± 2.2 vs.12.6 ± 2.6, P gt; 0.05). The size of new-formed islets in group C was significantly smaller than that in group A [(47.2 ± 19.6) μm vs. (119.6 ± 27.7) μm, P lt; 0.05]. The immunofluorescence staining showed that new-formed islets of group C expressed insulin protein. RT-PCR showed that the microdissected EGFP+ cells of group C expressed insulin mRNA and PDX-1 mRNA. FISH showed that the new-formed islet cells of group C contained SRY gene in Y chromosome and insulin double positive cells. Conclusion BMSCs can differentiate into IPCs in diabetic pancreatic microenvironment of pigs.
ObjectiveTo investigate the effects and mechanisms of differentiation of bone marrow mesenchymal stem cells (BMSCs) into insulin producing cells (IPCs) induced by injured pancreatic tissue extract of rat. MethodsEighty 6-week-old Sprague Dawley rats were selected. Forty rats underwent removal of 60% pancreas and the injured pancreas tissue was obtained after 48 hours to prepare the injured pancreatic tissue extract; and normal pancreatic tissue extract was prepared from the other 40 rats. The BMSCs were isolated from the tibia and femur of 4-week-old Sprague Dawley rats. BMSCs at passage 3 were co-cultured with rat injured pancreatic tissue extract as experimental group, with rat normal pancreatic tissue extract as normal control group, and with cell culture medium as blank control group for 14 days. The expressions of pancreas development related genes and proteins were detected, and cell morphological changes were observed. Then the C peptide positive cell rate was detected by flow cytometry analysis and insulin secretion levels were detected by glucose stimulation experiment at 14 days. ResultsInjured pancreatic tissue extract can induced BMSCs differentiating into IPCs. The pancreatic development related genes of pancreatic duodenal homeobox 1 (PDX-1), islet 1, Nkx6.1, glucose transporter type 2, proprotein convertase 2, neurogenin 3, and somatostatin were expressed sequentially in the differentiation process of experimental group; mature pancreatic proteins of PDX-1, insulin, C peptide, Nkx6.1 also were expressed. But there was no morphological changes and expression of pancreatic development related genes and proteins in normal control and blank control groups. The C peptide positive cell rate of experimental group (13.8%±1.8%) were significantly higher than those of normal control and blank control groups (1.6%±0.4%) (P<0.05). The insulin secretion of experimental group was significantly higher than that of normal control and blank control groups (P<0.05), but it was 1/40 and 1/47 of natural islet cells (P<0.05). ConclusionAfter pancreatic injury, injured pancreas would secrete transcription proteins related to development, differentiation, and repair of pancreas, which can promote the differentiation of BMSCs into IPCs.
ObjectiveTo observe the clinical effect of Lacosamide (LCM) in the treatment of children with intractable epilepsy.Methods41 cases of refractory epilepsy patients who received LCM from March to July 2019 in department of Neurology, General Hospital of Henan Province were collected which included 21 males, 20 females, age were 4.6 ~ 15.5 years, average (7.21±3.06) years, And the efficacy of LCM was observed through blank control study.ResultsAfter LCM was added to the blank self-control group, the frequency of epileptic seizures was significantly reduced during the follow-up period of 3 months and 6 months, with statistically significant difference (P<0.05), and the mental state of the children was effectively improved, but there was no statistical significance between focal refractory epileptic seizure and comprehensive refractory epileptic seizure (P>0.05).ConclusionsLCM is a new kind of the third generation of antiepileptic drug. The addition use of LCM can effectively reduce the seizure frequency and improve mental state in children with refractory epilepsy.
ObjectiveWe have summarized the clinical features of some refractory or genetically related children with epilepsy in clinical diagnosis and treatment and carried out the two generation of high-throughput gene sequencing and generation of verification on them. To analyze the relationship between mutant genes and epilepsy, to understand the genetic pattern of children and to look for possible pathogenic or disease causing mutation.MethodsEstablish a complete pedigree database for 95 children and their parents diagnosed in pediatric neurology clinic in our hospital from septeuber 2014 to Deceln ber 2016, and carry out gene testing on them by using two generation high-throughput gene sequencing. Then we have the analysis on the basis of clinical features and gene type in children.ResultsRefractory or genetically related children had a smaller age range and had a variety of clinical features. Most of them (47/95, 49.5%)needed two or more drugs for treatment; 28.4% of them was controlled which was about 27cases; 21.1% of them was effective which was about 20 cases; 33.7% of them was marked which was about 32 cases; 12.6% of them was of no effect which was about 12 cases; 4.2% of them was missed which was about 4 cases. a small number of children (18/95, 18.9%)had poor prognosis and accompanied with exercise and mental retardation. Genotype detection results: pathogenic genes of total 16 cases (16.8%)were cleared; there were about a total of 21 cases (22.1%)of possible pathogenic gene; there were about a total of 30 cases (31.6%)of non pathogenic gene; a total of 28 cases were not detected mutated gene which was about 29.5%.ConclusionsWe have found two new virulence gene of CASK and BRAF which had few reports in China and expanded the number of genes associated with neural development and epilepsy associated genes; the clinical characteristics of SCNIA gene mutations in Dravet syndrome were more serious which include earlier onset, frequent seizures and poor treatment effect; most children with specific causative genes required the combined use of two or more Anti-epileptic drugs, which has difficulties in treatme.
ObjectiveTo recognize the convulsion caused by hypoglycemia, and to analyze its genotype and clinical phenotype, so as to deepen the understanding of hyperinsulinemia.MethodFull exon detection were performed on 2 children with hypoglycemia and convulsions, who had been treated with antiepileptic drugs for 1 year in pediatric neurology department, Henan Provincial People’s Hospital in 2012 and 2014 respectively, but with poor curative effect.ResultABCC8 gene mutations were found in a child. The mutations located in Chromosome 11, with the nucleic acid changes of c.4607C>T (exon38) and the amino acid change of p.A1536V, rs745918247. The inheritancemode of ABCC8 gene could be autosomal dominant or autosomal recessive inheritance. Both of the parents were wild type on this genelocus. The gene mutation is associated with type 1 familial hyperinsulinemic hypoglycemia/nesidioblastosis. The other child was carrying GLUD1 gene mutation, witch is located in chromosome 10, with the nucleic acid changes of c.1498G>A (exon12) and the amino acid change of p.A500T. The inheritance mode of GLUD1 gene is autosomal dominant andthe child’s parents were both wild type. This gene mutationis associated with type 6 familial hyperinsulinemic hypoglycemia/nesidioblastosis. The 2 mutations have not been reported, which are new mutations.ConclusionMutations in these 2 gene loci may be the underlying cause of hypoglycemic convulsions, and are the best explanation for the poor convulsionscontrol of antiepileptic drugs.
ObjectiveTo investigate the clinical characteristics and genetic phenotype of mitochondrial myopathy associated with lactic acidemia and stroke-like seizure syndrome (MELAS) in DNA A3243G mutation, and to improve the clinical understanding and diagnosis.MethodsThe clinical data and imaging characteristics of 4 patients with DNA A3243G mutation-related MELAS syndrome who were diagnosed and treated in the Department of Pediatric Neurology, Henan Provincial People's Hospital from June 2017 to June 2018 were retrospectively reviewed.ResultsOf the 4 patients, 3 were caused by convulsions, 1 was caused by dizziness, and the MELAS syndrome caused by mitochondrial DNA A3243G mutation was confirmed by genetic testing. The patients were treated with anti-epilepsy drugs. The patients were followed up for at least 1 year, and 2 of 4 patients were stable, 1 patient still had seizures, and 1 patient did not improved.ConclusionsThe clinical phenotypic heterogeneity of patients with DNA A3243G mutation-related MELAS syndrome is caused by the " heterogeneity” and " threshold effect” of DNA mutation. The mutation rate of DNA A3243G is as high as 80%. In the era of promoting precision medicine, genes examination can help early diagnosis and early treatment of MELAS syndrome as well as improve the quality of life of patients and improve the prognosis.