Project description:Organ-on-a-chip platforms are utilized in global bioanalytical and toxicological studies as a way to reduce materials and increase throughput as compared to in vivo based experiments. These platforms bridge the infrastructure and regulatory gaps between in vivo animal work and human systems, with models that exemplify active biological pathways. In conjunction with the advent of increased capabilities associated with next generation sequencing and mass spectrometry based ‘-omic’ technologies, organ-on-a-chip platforms provide an excellent opportunity to investigate the global changes at multiple biological levels, including the transcriptome, proteome and metabolome. When investigated concurrently, a complete profile of cellular and regulatory perturbations can be characterized following treatment with specific agonists. In this study, global effects were observed and analyzed following liver chip exposure to the chemical warfare agent, VX. Even though the primary mechanism of action of VX (i.e. acetylcholinesterase inhibition) is well characterized, recent in vivo studies suggest additional protein binding partners that are implicated in metabolism and cellular energetic pathways. Also, secondary toxicity associated with peripheral organ systems, especially in human tissues, is not well defined. Our results demonstrate the efficacy of utilizing an organ-on-a-chip platform as a surrogate system to traditional in vivo studies. This is realized by specifically indicating significant dysregulation of a number of cellular processes in response to VX exposure including but not limited to amino acid synthesis, drug metabolism, and energetics pathways.

Project description:Organ-on-a-chip platforms are utilized in global bioanalytical and toxicological studies as a way to reduce materials and increase throughput as compared to in vivo based experiments. These platforms bridge the infrastructure and regulatory gaps between in vivo animal work and human systems, with models that exemplify active biological pathways. In conjunction with the advent of increased capabilities associated with next generation sequencing and mass spectrometry based ‘-omic’ technologies, organ-on-a-chip platforms provide an excellent opportunity to investigate the global changes at multiple biological levels, including the transcriptome, proteome and metabolome. When investigated concurrently, a complete profile of cellular and regulatory perturbations can be characterized following treatment with specific agonists. In this study, global effects were observed and analyzed following liver chip exposure to the chemical warfare agent, VX. Even though the primary mechanism of action of VX (i.e. acetylcholinesterase inhibition) is well characterized, recent in vivo studies suggest additional protein binding partners that are implicated in metabolism and cellular energetic pathways. Also, secondary toxicity associated with peripheral organ systems, especially in human tissues, is not well defined. Our results demonstrate the efficacy of utilizing an organ-on-a-chip platform as a surrogate system to traditional in vivo studies. This is realized by specifically indicating significant dysregulation of a number of cellular processes in response to VX exposure including but not limited to amino acid synthesis, drug metabolism, and energetics pathways.

Project description:In this work, a microwell-chip was prepared and modified. The microwell-chip was used for extraction of metabolites and subsequent protein digestion. Next, direct electrospray ionization mass spectrometry (ESI-MS) was adopted for metabolome identification and a data independent acquisition (DIA)-MS approach was established for simultaneous proteome profiling and phosphoproteome analysis. In particular, application of this strategy provides a multi-omics view of cellular changes.

Project description:To facilitate collaborative research efforts between multi-investigator teams using DNA microarrays, we identified sources of error and data variability between laboratories and across microarray platforms and methods to accommodate this variability. RNA expression data were generated in seven laboratories, comparing two standard RNA samples using twelve microarray platforms. At least two standard microarray types (one spotted, one commercial) were used by all laboratories. Reproducibility for most platforms within any laboratory was typically good, but reproducibility between platforms and across laboratories was generally poor. Reproducibility between laboratories dramatically increased when standardized protocols were implemented for RNA labeling, hybridization, microarray processing, data acquisition and data normalization. Nonetheless, concordance could be found across different laboratories and platforms when data were analyzed in terms of enriched Gene Ontology categories. These findings indicate that microarray results generated by multiple sites and platforms can be comparable, and that multi-investigator teams will maximize data comparability by adopting a common platform and a common set of procedures to generate compatible data. Keywords: other

Project description:Omics research targets biomolecules such as proteins, lipids, and metabolites, providing a comprehensive view of biological systems. The field has seen significant advancements with the development of mass spectrometry (MS). However, the accuracy of quantitative analyses is crucial due to the expansion of omics applications. Accurate comparisons depend on sample preparation and normalization methods. Some biological samples, like tissues and feces, present inherent variations that challenge accuracy. Normalization aims to reduce these variations through pre-acquisition methods that equalize biomolecule content and post-acquisition methods that adjust instrument signals. Most research has focused on single-omics data and post-acquisition normalization. However, multi-omics research, essential for understanding complex biological systems, has not thoroughly evaluated normalization methods. This study evaluates three pre-acquisition normalization methods using methanol-chloroform-water extraction to enhance multi-omics data analysis. Our multi-omics data shows that the data is significantly different depending on the normalization methods and our optimized normalization method showed that there were significant multi-omics profile changes even with young mice tissue samples. Based on these findings, we suggest sample normalization based on total protein amount to minimize the sample variation and get an accurate comparison for multi-omics.

Project description:Omics research targets biomolecules such as proteins, lipids, and metabolites, providing a comprehensive view of biological systems. The field has seen significant advancements with the development of mass spectrometry (MS). However, the accuracy of quantitative analyses is crucial due to the expansion of omics applications. Accurate comparisons depend on sample preparation and normalization methods. Some biological samples, like tissues and feces, present inherent variations that challenge accuracy. Normalization aims to reduce these variations through pre-acquisition methods that equalize biomolecule content and post-acquisition methods that adjust instrument signals. Most research has focused on single-omics data and post-acquisition normalization. However, multi-omics research, essential for understanding complex biological systems, has not thoroughly evaluated normalization methods. This study evaluates three pre-acquisition normalization methods using methanol-chloroform-water extraction to enhance multi-omics data analysis. Our multi-omics data shows that the data is significantly different depending on the normalization methods and our optimized normalization method showed that there were significant multi-omics profile changes even with young mice tissue samples. Based on these findings, we suggest sample normalization based on total protein amount to minimize the sample variation and get an accurate comparison for multi-omics.

Project description:To facilitate collaborative research efforts between multi-investigator teams using DNA microarrays, we identified sources of error and data variability between laboratories and across microarray platforms and methods to accommodate this variability. RNA expression data were generated in seven laboratories, comparing two standard RNA samples using twelve microarray platforms. At least two standard microarray types (one spotted, one commercial) were used by all laboratories. Reproducibility for most platforms within any laboratory was typically good, but reproducibility between platforms and across laboratories was generally poor. Reproducibility between laboratories dramatically increased when standardized protocols were implemented for RNA labeling, hybridization, microarray processing, data acquisition and data normalization. Nonetheless, concordance could be found across different laboratories and platforms when data were analyzed in terms of enriched Gene Ontology categories. These findings indicate that microarray results generated by multiple sites and platforms can be comparable, and that multi-investigator teams will maximize data comparability by adopting a common platform and a common set of procedures to generate compatible data. Keywords: other

Project description:Epigenomic profiling by ChIP-seq is a prevailing methodology used to investigate chromatin-based regulation in biological systems, such as human disease, yet the lack of an empirical methodology to normalize amongst experiments has limited the usefulness of this technique. Here we describe a “spike-in” normalization method that allows the quantitative comparison of histone modification status across cell populations using defined quantities of a reference epigenome. We demonstrate the utility of this method in measuring epigenomic changes following chemical perturbations and show how control normalization of ChIP-seq experiments enables discovery of disease-relevant changes in histone modification occupancy.

Project description:Three AIEC strains were isolated from CD patients. We analyzed three types of cell: before adhesion and adhesion-invasion(control), after adhesion-invasion and after invasion. Proteins were assessed in an untargeted label-free bottom-up proteomic experiment using IDA approach (i.e. Information Dependent Acquisition) on Sciex TripleTOF 6600 Q-TOF mass-spectrometer couplet with LFQ (label-free quantification) by MaxQuant software. Dataset covers 54 samples (three biological replicates and two technical).

Project description:Plaque rupture and subsequent thrombus formation is responsible for the majority of clinical complications of atherosclerosis and nonetheless our understanding of what underlies plaque vulnerability and rupture is still sparse and mostly deductively based on animal models and in vitro studies. We adopted five different -omics platforms to compare ruptured atherosclerotic and advanced-stable tissue within the same carotid plaque specimen from 24 carotid endarterectomy patients. Segments designated as stable feature either a fibrous cap atheroma or pathological intimal thickening. Segments designated as ruptured include a thrombus and/or presented intraplaque hemorrhage. For the present study only those samples were selected for further analysis that were flanked by two segments of identical classification, be it stable (S) or ruptured (R); and were derived from CEA specimen that contained plaque segments of both classifications.