Delineation of cell subpopulations and cell-cell interactions
Understanding the complex interactions in the tumor microenvironment (TME) plays a pivotal role in the onset of cancer, the advancement of tumors, and the determination of the reaction against anti-cancer treatments.
Traditional studies fail to recognize the potential of studying the spatial arrangement of the TME and are therefore unable to completely uncover its intricacies. To overcome these limitations, we use quantitative image analysis based on multiplex immunohistochemistry to extract data from the TME.
Discover how our proprietary imaging platform helps identify drug targets in spatial environments and provides insights into treatment response for non-small cell lung cancer.
Spatial quantification of biomarkers within target tissues with image analysis platform
Exploring tissue-based biomarkers is a crucial component of pre-clinical/clinical drug development, as it can help identify new therapeutic targets, evaluate surrogate markers of drug effectiveness, and predict potential benefits of a candidate compound.
Using image analysis allows us to evaluate tissue biomarkers in greater detail and study cellular interactions in complex biological processes. Our digital pathology data analysis workflow allows the automation of cell segmentation and their classification to resolve the molecular architecture of the tissue.
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Cell deconvolution to estimate cell type abundance from spatial transcriptomic data within heterogeneous tissues
Central to spatial biology is the mapping of cell types across heterogenous tissues. This process helps us understand the relationship between cells in the context of disease and their role in response to treatment. Based on cell abundances, we identified different microenvironment cell subtypes within non-small-cell lung cancer (NSCLC) tissues and differentiated how they responded to checkpoint inhibitor therapy.
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Assessment of reproducibility in multiplex immunohistochemistry
Multiplex Immunohistochemistry (mlHC) is an advanced technique that can detect tissue-based biomarkers simultaneously, which transforms the traditional approach of immunohistochemistry. mlHC enables precision medicine in both research and clinical practice because it evaluates various proteins and their spatial distribution within single tissue sections at a cellular level.
Specific requirements are crucial for achieving high-quality staining and analysis, and to deem a mlHC assay as validated, it must be proven to be analytically reproducible.
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An automated complementary method for spatially resolved quantitative analysis of drugs and biomarkers
Having an initial understanding of drug distribution, quantification and target engagement within disease-relevant histological structures is critical in choosing more effective drug candidates. MALDI MSI unveils the quantitative distribution of label-free drugs, or biomarkers, providing valuable data that complements information obtained through traditional approaches.
Our optimized workflows offer solutions to problems that are sometimes encountered when you quantify drugs and biomarkers with MSI, and open the door for precision quantification of any molecule in specific regions of interest.
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Discover the intricacies of molecular landscapes through quantitative mass spectrometry imaging (QMSI)
Aliri’s proprietary imaging workflows will help you understand localization, quantification, and distribution of drugs at the site of action.
Studying drug efficacy at the site of action gives us valuable and unique insights into:
- Drug bioavailability
- Drug biodistribution
- Targeted tissue exposure
- On-tissue PK/PD
- Monitoring the drug effects through readout biomarkers (metabolites, lipids, genes expression, proteins)
Our QMSI spatial platform uses data analysis to conduct molecular distributions, and artificial intelligence to find patterns and make predictions. This advanced imaging technique allows you to visualize the molecule within tissues, and evaluate how prevalent the drug is within the histological region of interest.
Our high expertise in this area sets us apart from other CROs in pharma/bio industries and positions us as a leader in spatial bioanalysis and biology services.
Check out our infographic to learn more about our unique imaging platforms.
A guide to the advantages and disadvantages of sample preparation for small molecules
Accurate and reliable results in the drug discovery process rely heavily on the pivotal role of sample preparation. By adopting optimized sample preparation techniques, you can significantly improve the quality of your data.
Sample preparation for small molecules involves three primary modes:
- Protein precipitation
- Supported liquid exchange / liquid/liquid extraction
- Solid phase extraction
Our comprehensive guide offers valuable insights associated with preparing small molecule samples for analysis, including advantages and disadvantages of each preparation mode.
Veterinary Drug Analysis Services
Aliri has more than 18 years of experience providing state-of-the-art animal health regulatory bioanalytical services to support research and development initiatives. With a team of skilled scientists, advanced technologies, and regulatory expertise, we are committed to delivering accurate and reliable data to expedite project timelines and enhance animal health.
Aliri by the numbers:
- 45 animal health clients
- 300+ studies supported
- 70 compounds
- 100+ custom assays
- 150 biological fluids and tissues
Explore our assay experience, platforms, regulations and more:
WRIB 2023 Poster: Bimiralizib distribution in human skin biopsies after topical administration obtained by validated quantitative mass spectrometry imaging
Quantitative MALDI Mass Spectrometry Imaging (QSMI) can be used to determine drug distribution in first-in-human studies
At WRIB 2023, Shane Karnik, Senior Laboratory Director at Aliri, presented a poster about utilizing QSMI to determine Bimiralizib distribution in human skin biopsies.
Recent clinical trial results validate Bimiralizib distribution in human skin and showcase:
- Robustness of MALDI MSI method
- Approach not limited to dermatology; already applied in oncology
- Absolute quantification allowed to determine if the compound reached the site of action
- Method allows to characterize small compound PK in clinical trial
- Method allows the characterization of the target engagement
Download our poster about utilizing QSMI to determine drug distribution.
ATP detection by quantitative mass spec imaging (QMSI)
As leaders in the field of spatial bioanalysis, Aliri utilizes state-of-the-art imaging techniques to evaluate localization and distribution of molecules within tissue microenvironments.
Our unique approach utilizing by quantitative mass spectrometry imaging (QMSI) for pathway detection allows us to:
- Stabilize the ATP pathway with an inhibitor cocktail
- Normalize the signal intensities from the raw data sets
- Perform the absolute quantification of the ATP
- Calculate the relative quantification of the ADP and AMP
Learn how we can help you leverage ATP pathway detection with QMSI