Preparation
DNA Removal
Purification
Elution
Created by Ahmed Kamel
Silica Spin-Column Method

Extraction & Purification of
RNA from FFPE Tissue

A Mechanistic Guide to the Silica Spin-Column Protocol

Follow this interactive walkthrough to understand every step of the protocol — what you do, and why it works at the molecular level.

The Protocol Blueprint

Phase 1

Preparation

  • 1 Deparaffinization
  • 2 Lysis & Crosslink Reversal
Phase 2

DNA Removal

  • 3 DNase Digestion
Phase 3

Purification

  • 4 RNA Binding
  • 5 Stringent Wash
  • 6 Desalting Wash
  • 7 Dry Spin
Phase 4

Elution

  • 8 RNA Elution
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Phase 1 · Preparation

Step 1: Deparaffinization (Wax Removal)

Paraffin Wax
Exposed Tissue

Action

What You Do

Add a deparaffinization solvent to the pre-prepared FFPE tissue samples, followed by centrifugation and ethanol washes.

Function

Why It Works

Dissolves and completely removes the embedding paraffin wax. This exposes the biological tissue, allowing the subsequent aqueous buffers and enzymes to effectively penetrate the cells.

Phase 1 · Preparation

Step 2: Tissue Lysis & Reverse Crosslinking

The Enzyme Proteinase K digests proteins & inactivates RNases
The Heat Reverses formalin-induced chemical cross-links
RNA Protection Fragile RNA freed without degradation

Action

What You Do

Add Tissue Lysis Buffer (optimized for RNA) and Proteinase K, then incubate at specific elevated temperatures.

Function

Why It Works

The buffer and enzyme work together to digest cellular proteins and instantly inactivate destructive RNases. The heat incubation is crucial for reversing formalin-induced cross-links, freeing the fragile RNA molecules from protein complexes without degrading them.

Phase 2 · DNA Removal

Step 3: DNase Digestion (Genomic DNA Removal)

Action

What You Do

Apply DNase I enzyme (can be done in-solution or directly on-column depending on the kit).

Function

Why It Works

Specifically degrades massive genomic DNA strands into tiny, soluble fragments that will later wash away. Without this, gDNA would co-purify and severely contaminate the final RNA yield.

Phase 3 · Purification

Step 4: RNA Binding to Silica

Silica Membrane
+++

Action

What You Do

Add Binding Buffer (high chaotropic salt concentration) and pure Ethanol to the sample, then transfer to a silica spin-column. Centrifuge.

Function

Why It Works

Ethanol and chaotropic salts dehydrate the RNA and disrupt the hydration shell of the silica membrane. This forces the negatively charged RNA to form a strong "salt bridge" with the silica, anchoring the RNA to the column while contaminants flow through.

Phase 3 · Purification

Step 5: Stringent Wash (Removing Protein/Salt)

Action

What You Do

Apply Wash Buffer 1 (contains moderate chaotropic salts and ethanol) to the column. Centrifuge.

Function

Why It Works

Washes away residual proteins, lipids, and some chaotropic salts. The ethanol ensures RNA stays tightly bound to the silica while contaminants are released.

Phase 3 · Purification

Step 6: Desalting Wash

Action

What You Do

Apply Wash Buffer 2 (mostly ethanol) to the column. Centrifuge.

Function

Why It Works

Removes any remaining chaotropic salts from the previous buffers. High ethanol content maintains the RNA-silica bond.

Phase 4 · Elution

Step 7: Dry Spin

Action

What You Do

Centrifuge the column at max speed for 1-2 minutes with the lid open or in a fresh empty tube.

Function

Why It Works

Completely removes any residual ethanol from the wash buffers. Ethanol carryover can inhibit downstream enzymatic reactions (like PCR or sequencing).

Phase 4 · Elution

Step 8: Elution (Pure RNA Extraction)

Action

What You Do

Transfer the column to a fresh RNase-free tube. Add RNase-free water directly to the center of the silica membrane. Incubate briefly, then centrifuge.

Function

Why It Works

The water lacks chaotropic salts and ethanol, which rehydrates the silica membrane and breaks the salt bridge. The pure RNA detaches from the membrane and flows into the collection tube.

Protocol Complete!

You have successfully extracted pure, intact RNA from FFPE tissue. The RNA is now ready for downstream applications such as RT-qPCR or RNA-Seq.

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Created by Ahmed Kamel