Protein microarray platform for the multiplex analysis of biomarkers in human sera

Many biomarkers are currently used to monitor patients in clinical studies. Technologies which evaluate, validate and monitor biomarkers in a cost effective and efficient manner are a necessity. Here we describe the development, validation and implementation of a protein microarray platform for the quantitative and simultaneous analysis of six proteins: IL-1beta, IL-1ra, IL-6, IL-8, MCP-1 and TNFalpha. The platform utilizes a 96-well plate as a solid support on which antibodies are immobilized using non-contact piezoelectric printing. The reaction is based on a sandwich ELISA and the signal is quantified by chemiluminescence with a CCD camera. The robustness and reproducibility of the methodology was investigated using the Food and Drug Administration (FDA) regulatory guidelines for pharmacokinetic assay validation, in which a spike-recovery validation test was elaborated and run over 3 days. The method was shown to be both quantitative and reproducible, with assay accuracy between 70% and 130%, and an assay precision of less than 30%. In addition, protein microarray performance was compared with the classical ELISA approach. Sera collected from a total of 78 individuals were assayed using both approaches. Correlation coefficients (R2) between the two technologies were calculated for each of the analytes: 0.90 for IL-1beta, 0.60 for IL-1ra, 0.93 for IL-6, 0.96 for IL-8, 0.94 for MCP-1 and 0.95 for TNFalpha. The results obtained demonstrate the applicability of this protein microarray for quantitative and simultaneous analysis of IL-1beta, IL-1ra, IL-6, IL-8, MCP-1 and TNFalpha in clinical samples.     

A Comparative Study of Psychosocial Interventions for Internet Gaming Disorder Among Adolescents Aged 13–17 Years

International Journal of Mental Health and Addiction - The present study is a quasi-experimental, prospective study of interventions for internet gaming disorder (IGD). One hundred four parents and...     

Osteoblastic differentiation potential of human amniotic fluid-derived mesenchymal stem cells in different culture conditions

Osteoporosis is a bone degenerative disease characterized by a decrease in bone strength and an alteration in the osseous micro-architecture causing an increase in the risk of fractures. These diseases usually happen in post-menopausal women and elderly men. The most common treatment involves anti-resorptive agent drugs. However, the inhibition of bone resorption alone is not adequate for recovery in patients at the severe stage of osteoporosis who already have a fracture. Therefore, the combination of utilizing osteoblast micro mimetic scaffold in cultivation with the stimulation of osteoblastic differentiations to regain bone formation is a treatment strategy of considerable interest. The aims of this current study are to investigate the osteoblastic differentiation potential of mesenchymal stem cells derived from human amniotic fluid and to compare the monolayer culture and scaffold culture conditions. The results showed the morphology of cells in human amniotic fluid as f-type, which is a typical cell shape of mesenchymal stem cells. In addition, the proliferation rate of cells in human amniotic fluid reached the highest peak after 14 days of culturing. After which time, the growth rate slowly decreased. Moreover, the positive expression of specific mesenchymal cell surface markers including CD44, CD73, CD90, and also HLA-ABC (MHC class I) were recorded. On the other hand, the negative expressions of the endothelial stem cells markers (CD31), the hematopoietic stem cells markers (CD34, 45), the amniotic stem cells markers (CD117), and also the HLA-DR (MHC class II) were also recorded. The expressions of osteoblastogenic related genes including OCN, COL1A1, and ALP were higher in the osteogenic-induced group when compared to the control group. Interestingly, the osteoblastogenic related gene expressions that occurred under scaffold culture conditions were superior to the monolayer culture conditions. Additionally, higher ALP activity and greater calcium deposition were recorded in the extracellular matrix in the osteogenic-induced group than in the culture in the scaffold group. In summary, the mesenchymal stem cells derived from human amniotic fluid can be induced to be differentiated into osteoblastic-like cells and can promote osteoblastic differentiation using the applied scaffold.