Top Blood Enhancement Chemicals for Latent Prints: What You Need to Know

Bloody prints look promising—until you start processing. Between fragile ridge detail, unpredictable surfaces, and chemical interactions you didn’t see coming, choosing the right method (and one of the top blood enhancement chemicals) is more complicated than just “spray and develop.”

If you’ve ever stood over a bloodstained surface thinking, Should I prioritize the bloody prints, the natural latent prints—or try to recover both?—you’re not alone. Processing bloody latent prints takes more than knowing your reagents. You need to understand the science behind them, weigh your priorities on a case-by-case basis, and choose the right chemical for the job—without compromising your evidence or your safety.

In this post, we’re breaking down the top blood enhancement chemicals used in latent print processing—how they work, when to use them, and how to avoid the common mistakes that trip up even seasoned techs.

Let’s dive into the chemical lineup that could make or break your next bloody print case.

Disclaimer: Always follow your agency’s policies and procedures when processing evidence, and consult the safety data sheets (SDS) for each chemical before use.

What Are Blood Enhancement Chemicals?

Blood enhancement chemicals are specialized reagents used in forensic science to visualize and document blood evidence—especially when stains are faint, diluted, or transferred in ways that make them hard to see with the naked eye. These chemicals work by reacting with components in blood, such as proteins or heme group, to produce a visual or fluorescent contrast, making the impressions easier to observe, photograph, and preserve.

To use them effectively, you need to understand both their strengths and their limitations. Many reagents require a fixative step beforehand to prevent ridge detail from washing away during processing. And depending on the chemical, enhancement may appear under normal lighting—or require an alternate light source (ALS).

When used properly, these reagents help highlight fragile or faint ridge detail that could be easily overlooked—or accidentally lost or damaged—during development.

Related: “How to Process Bloody Surfaces: A Step-by-Step Guide for Latent Print Enhancement”

Factors to Consider When Choosing a Blood Reagent

Choosing the right blood enhancement chemical isn’t a one-size-fits-all decision—and not to sound dramatic, but it can be the difference between preserving key evidence or unintentionally destroying it. When working with bloody impressions, the chemical you choose must align with the surface type, condition of the blood, and your investigative goals.

Here are the key factors you need to consider:

1. Surface Type (e.g. porous vs. non-porous)

Certain reagents work best on non-porous surfaces, while others may cause background staining on porous items. Always consider the material you’re processing before selecting a reagent.

2. Condition of the Blood (e.g. wet vs. dried)

The condition of the deposit affects visibility and processing steps. Wet or recently deposited blood may still smear or diffuse without a fixative, while dried blood tends to hold its shape better but may require longer development times for reagent penetration.

3. Fixative Requirements

Some reagents require a fixative to preserve blood detail during processing. Skipping this step can lead to smudged or lost impressions.

4. Detection Method

Reagents vary in how they’re visualized—some fluoresce under an alternate light source (ALS), while others are seen under white light. Match the reagent to your available forensic tools.

5. Investigative Goals

If you’re targeting both blood and natural latent components, sequence your reagents accordingly. Some chemicals won’t reveal eccrine/sebaceous prints.

6. Safety

Many reagents contain hazardous chemicals that require PPE, proper ventilation, and careful handling. Some are safer for field use, while others are best reserved for lab settings with fume hoods and additional controls.

7. Shelf Life

Check whether your reagent has a short working life or long-term stability. Fresh chemistry is key for reliable, consistent results.

Top Blood Enhancement Chemicals Used in Forensics

Once you’ve evaluated the casework and considered your priorities, it’s time to choose the chemical that gives you the best shot at recovering usable prints. Below, we’re breaking down the most widely used blood enhancement reagents in forensic latent print processing—each with its own strengths, limitations, and ideal use cases.

You might be wondering why popular tools like BlueStar or luminol aren’t on this list. While they’re excellent for detecting latent bloodstains—especially in cases where a scene has been cleaned or clothing has been washed—they’re not ideal for enhancing ridge detail. These chemiluminescent reagents are designed to confirm the presence of blood, not to develop or preserve fingerprint patterns.

That’s why this list focuses on blood enhancement chemicals specifically formulated to highlight ridge detail. We’ll walk through how each reagent works, what surfaces and conditions it’s best suited for, and what to watch out for when applying it in the field or lab.

Let’s break it down.

Acid Fuchsin (Hungarian Red)

• Best For: Non-porous or semi-porous surfaces with light-colored or patterned background
• How It Works: Binds to proteins in blood, creating a deep pink to purple stain that fluoresces under an alternate light source
• Application: Usually applied via immersion, pipette, or wash bottle (fixative solution strongly recommended before application)
• Pros:
  • Strong visual and fluorescent properties
• Cons:
  • Background staining is a risk on porous surfaces
  • Not useful for non-blood based prints

Acid Yellow 7

• Best For: Non-porous or semi-porous surfaces with dark-colored or patterned background
• How It Works: Binds to proteins in blood, fluoresces bright yellow under ALS
• Application: Usually applied via immersion, pipette, or wash bottle (fixative solution strongly recommended before application)
• Pros:
  • Fluorescent contrast on dark or complex backgrounds
• Cons:
  • Background staining is a risk on porous surfaces
  • Not useful for non-blood based prints

Amido Black

• Best For: Non-porous or semi-porous surfaces with light-colored background
• How It Works: Binds to proteins in the blood, producing a dark blue or black stain
• Application: Usually applied via immersion, spray, or wash bottle
• Pros:
  • Strong visual contrast in white light
• Cons:
  • Background staining is a risk on porous surfaces
  • Not useful for non-blood based prints
  • Not fluorescent

Coomassie Blue

• Best For: Non-porous or semi-porous surfaces with light-colored background
• How It Works: How It Works: Binds to proteins in the blood, producing a deep blue stain
• Application: Usually applied via immersion, pipette, or wash bottle (fixative solution strongly recommended before application)
• Pros:
  • Strong visual contrast in white light
• Cons:
  • Background staining is a risk on porous surfaces
  • Not useful for non-blood based prints
  • Not fluorescent

LCV (Leucocrystal Violet)

• Best For: Non-porous or semi-porous surfaces with light-colored background
• How It Works: Reacts with the heme group of hemoglobin in blood, producing a deep violet color
• Application: Lightly spray onto the surface
• Pros:
  • Excellent contrast on light backgrounds
  • Can serve as a presumptive test for blood
• Cons:
  • Background staining is a risk on porous surfaces
  • Not useful for non-blood based prints
  • Not fluorescent

Merbromin

• Best For: Non-porous or semi-porous surfaces with dark-colored or patterned background
• How It Works: Reacts with the heme group of hemoglobin in blood, fluoresces bright green under ALS
• Application: Spray or brush lightly onto the surface. Requires careful handling to avoid background staining.
• Pros:
  • Fluorescent contrast on dark or complex backgrounds
  • Can serve as a presumptive test for blood
• Cons:
  • Background staining is a risk on porous surfaces

Want to know which reagent is best for your casework? Be sure to match the chemical to your surface type, investigative priorities, and lab capabilities. For additional guidance, check out our Latent Print Processing Flowchart and Mini-Courses to help you make informed, evidence-based decisions.

Field vs Lab Application: Where to Use Each Chemical

Not all blood enhancement chemicals are created equal—especially when it comes to where they should be used. Some are safe and simple enough for the field, while others are best reserved for the lab due to safety concerns, equipment needs, or procedural complexity.

Here’s a quick breakdown of ideal use environments for the six most common reagents:

In the field, simplicity and safety are key. In the lab, you can afford more complex procedures that may require fume hoods or extended processing time.

⚠️ Keep in Mind:

• Even “field-safe” reagents still require proper PPE and handling.
• If using chemicals at the scene, always consider ventilation, containment, and photography needs before application.

Pro Tip: Download and print our Blood Reagent Processing Guides for each chemical to keep in your field kit or lab as a quick reference (coming soon!). They’re perfect for on-scene use when time and clarity matter most.

Blood Reagent Shelf Life: What You Need to Know

Blood enhancement chemicals don’t last forever—and using degraded or expired reagents can compromise ridge detail and lead to inconsistent results. Here’s a quick-reference guide to common blood reagents and how to store them properly:

⚠️ Disclaimer: This information is intended as a general reference and does not replace manufacturer recommendations. Always refer to the manufacturer’s guidelines and the chemical’s Safety Data Sheet (SDS) for specific storage, handling, and shelf life information. We are not responsible for misuse or misapplication of chemical reagents.

Tips to Extend Shelf Life:

• Always store reagents in clearly labeled, airtight amber bottles.
• Keep them away from direct light and high temperatures.
• Refrigerate when recommended—but never freeze unless specified.
• Inspect solutions regularly for changes in color, clarity, or odor.

Related: “Blood Reagent Expiration: How Long Do Your Chemicals Really Last?“

Common Mistakes to Avoid When Using Blood Enhancement Chemicals

Even experienced techs can slip up. Watch for these common pitfalls:

• Overapplication: Less is more! Drowning your print in reagent can destroy detail.
• Using expired reagents: Always double-check your labels before use.
• Wrong surface choice: Some reagents work poorly on certain materials. Know your substrates.
• Skipping proper documentation: If you’re using fluorescence, make sure to test multiple wavelengths!

Conclusion

Enhancing bloody fingerprints isn’t just about “spray and pray.” The chemical you choose, the way you apply it, and how well you understand its limitations all play a role in whether or not you recover usable ridge detail.

When you know how to work with LCV, Amido Black, Coomassie Blue, Merbromin, Acid Yellow 7, and Acid Fuchsin—and when to avoid them—you increase your chances of preserving key evidence without compromising safety or case integrity.

Looking for more support? Explore our blood reagent processing guides and mini-courses designed just for professionals like you. Stay sharp, stay safe, and happy processing!

Level Up Your Bloody Print Processing!

Join us live on May 21 for our free webinar:
Enhancing Bloody Prints: A Blueprint for Chemical Selection and Documentation

Walk through real-world challenges of developing and documenting bloody prints with our expert instructors. Whether you’re just getting started or want to sharpen your skills, this live session will help you:

✅ Understand how blood composition affects enhancement
✅ Choose the right chemical based on surface, contrast, and safety
✅ Prepare evidence for clear documentation under visible and ALS lighting

Bonus: Get a sneak peek at our newest field-ready tools, including mini-courses and quick-reference guides for six major blood reagents.

Can’t make it live? No worries—you’ll get access to the replay, too.

Related Reading:

• How to Process Bloody Surfaces: A Step-by-Step Guide for Latent Print Enhancement
• Field vs Lab Blood Reagents: Choosing the Right One for Every Case
• Blood Reagent Expiration: How Long Do Your Chemicals Really Last?