Singulator 200+ Resources

Brain FFPE tissue creates unique nuclei isolation challenges. Myelin debris, lipid contamination, and fragile neuronal nuclei require controlled automated processing to preserve cell-type diversity for single-nucleus sequencing.

Process brain tumor FFPE from surgical resections on the Singulator 200+. Preserve cancer cells and immune populations for snRNA-seq and spatial analysis.

How the Singulator 200+ preserves fragile neuronal nuclei from irreplaceable postmortem brain tissue. Automated FFPE processing for Alzheimer's, brain tumors, and brain atlases.

Extract nuclei from FFPE brain tissue for Alzheimer's, Parkinson's, and Lewy body research. Longitudinal cohorts, cell-type preservation, and disease staging on the Singulator 200+.

Pair spatial transcriptomics with snRNA-seq from the same FFPE brain block. Block allocation, platform selection, and nuclei quality for multi-omic brain studies.

Get high-quality nuclei from limited postmortem brain FFPE sections. Process NIH biobank allocations, hospital archives, and surgical specimens on the Singulator 200+.

Practical guide to postmortem brain FFPE challenges: necropsy timing, fixation variability, biobank sourcing, myelin debris, and how the Singulator 200+ standardizes nuclei extraction.

Standardize brain FFPE nuclei extraction across consortium sites with the Singulator 200+. Eliminate operator variability, prevent batch effects, and scale for atlas projects.

Ronan Chaugnet from Memorial Sloan Kettering shares several years of head-to-head benchmarking data comparing nuclei extraction platforms for FFPE tissue. The Singulator 200+ and Miltenyi GentleMACS both outperformed manual approaches across glioblastoma, liver, lung, pancreas, and tumor samples, with the Singulator 200+ standing out for its fully automated, enzyme-free workflow. Ronan also walks through three methods his lab has built on top of automated FFPE extraction: 10X Genomics FLEX for high-quality gene expression, PERFF-Seq for sorting rare cell populations by RNA markers, and GIFT-Seq for detecting 600+ mutations at single-cell resolution from archival tissue.

This protocol describes how to isolate, count, and prepare single nuclei from FFPE (formalin-fixed, paraffin-embedded) tissues for single-nuclei sequencing assays using the Singulator 200+ platform. Deparaffinization and rehydration of the tissue using solvent and various concentrations of ethanol are conducted on the Singulator 200+ platform along with automated nuclei isolation.

Brain atlases are being built. Archival tissue is finally talking. How standardized nuclei extraction and platform-agnostic analysis are solving neuroscience's oldest cold cases.

Manual extraction of nuclei from FFPE brain tissue destroys 50 to 60 percent of starting material. Fragile neurons die first, leaving biased results. Here is what goes wrong.

Millions of FFPE brain tissue blocks sit in biobanks worldwide, holding decades of evidence about Alzheimer's, Parkinson's, and neurodegenerative diseases. What if we could reopen these cases?

Manual FFPE processing destroys fragile neuronal nuclei and produces variable results. The Singulator 200+ automates the workflow with a two-cartridge system that delivers consistent, operator-independent results from irreplaceable brain tissue.

NIH biobanks give you one allocation of irreplaceable brain tissue. Manual processing destroys 50-60% before analysis begins. The extraction method is the real variable.

End-to-end protocol walkthrough from FFPE block selection through deparaffinization, nuclei isolation, quality control, library preparation, sequencing, and data analysis using the Singulator 200+.

How the Singulator 200+ GREEN cartridge automates FFPE deparaffinization and rehydration, eliminating toxic solvents, fume hoods, and manual ethanol series from nuclei extraction workflows.

Practical guide to connecting Singulator 200+ FFPE nuclei with downstream analysis platforms including 10x Chromium Flex, Xenium, ATAC-seq, Visium, and MERFISH, covering quality requirements, expected yields, and multi-platform study design.

Practical guide to preparing FFPE tissue inputs for the Singulator 200+ automated nuclei extraction platform, covering curl thickness selection, tissue mass requirements, block age effects, quality assessment, and handling difficult or precious specimens.

Practical troubleshooting guide for the Singulator 200+ FFPE nuclei extraction workflow, covering the five most common problem categories: low yield, excessive debris, poor RNA quality, batch-to-batch variability, and cartridge/instrument errors.

Practical strategies for maximizing nuclei recovery from limited FFPE tissue on the Singulator 200+, covering block quality assessment, sectioning waste reduction, the pilot curl approach for irreplaceable specimens, handling needle biopsies and crumbly blocks, and preserving nuclei yield post-processing.

Quality assessment of nuclei isolated from FFPE tissue using the Singulator 200+, covering yield measurement, DAPI staining for morphology, DV200 RNA quality metrics, erythrocyte contamination assessment, and structured go/no-go decision frameworks before downstream sequencing.

The most comprehensive tissue dissociation reference available. Interactive protocols for single-cell isolation and nuclei extraction across 57+ tissue types with community and Singulator-optimized methods.

How formalin-fixed paraffin-embedded tissue archives hold enormous potential for single-cell genomics, and how the Singulator 200+ automates the nuclei extraction workflow to unlock that potential

Somewhere in your institution, there's a dusty shelf. Sitting on it: thousands of tissue blocks. Each one holds decades of clinical history. Patient outcomes. Treatment responses. Disease progression. Data that took years to collect. And can you blame researchers for walking past it?

Here's a weird fact: the same chemical that saves your sample also traps everything useful inside it. Think about laminating a document. Great for protection. Terrible if you need to edit what's inside. That's formalin. And for decades, nobody could undo the damage.

Third try. Third failure. The fume hood is running. The xylene smells terrible. And the protocol that worked last Tuesday is giving nothing but debris. Sound familiar? Here's the question nobody was asking: Is it your technique—or is it the physics?

What if that two-hour protocol took sixty minutes? What if twelve pipetting steps dropped to four? What if the fume hood became optional? These aren't hypotheticals. This is what purpose-built automation looks like. And the difference isn't just time.

Behind every tissue block is a patient who said yes. Yes to collection. Yes to research. Yes to the hope that their gift might help someone else. They trusted the science. The question now: are the protocols worthy of that trust?

Fresh vs. Frozen: Which Side Are You On? Description: The debate between fresh tissue (whole cells) and frozen tissue (nuclei) divides labs. We explore why fresh dissociation often creates a "map of a disaster" through stress artifacts, and why frozen nuclei offer the unbiased, stable truth required for atlas-scale science.

The List is Good, But Is the Map Better? Description: Single-nucleus sequencing gives you the "List" of cell types, but Spatial Transcriptomics gives you the "Map." Discover how combining these technologies creates a high-resolution "Precision Point," and how one automated platform can serve as the engine for both workflows.

From the hidden world of glia to the final 3D atlas, the journey of modern neuroscience relies on one foundational step: sample preparation. We conclude our series by challenging researchers to prioritize clean, reproducible input to build the definitive map of the human brain.

For a century, neuroscience focused exclusively on the neuron, dismissing glia as mere "packing peanuts." Discover how single-nucleus sequencing revealed the active, critical role of the brain's immune and support systems—and why this shift changes everything for Alzheimer's research.

What is Ruining Your Frozen Experiments? Description: Every great story needs a villain. In frozen brain tissue processing, that villain is myelin debris. Learn how lipid contamination clogs microfluidics and ruins data, and see how the Singulator’s automated Protocol DP0006 neutralizes this threat to unlock biobank archives.