Forensics Expert Explains How to Analyze Bloodstain Patterns | WIRED
Summary
TLDRMatthew Steiner, a certified Senior Crime Scene Analyst, educates on the intricacies of bloodstain pattern analysis in forensics. The video covers various patterns like passive drops, transfer stains, and spatter, influenced by factors like surface texture and gravity. It delves into the importance of safety at crime scenes, the significance of not contaminating evidence, and the techniques used to interpret patterns, such as calculating the area of convergence and angle of impact. The video emphasizes the complexity and the art of observation in forensic science, providing a detailed look into the investigative process.
Takeaways
- 🔍 Matthew Steiner, a certified Senior Crime Scene Analyst, introduces various techniques for analyzing bloodstain patterns.
- 🧬 The video explains that collecting DNA from a person without consent is illegal and focuses on legitimate forensic methods.
- 👔 Safety at crime scenes is paramount, with personal protective equipment (PPE) like gloves, eye protection, and Tyvek suits used to prevent contamination.
- 🐏 Defibrillated sheep's blood is used for demonstration, devoid of fibrin to prevent clotting, which would complicate the analysis.
- 🔎 Bloodstain pattern analysis involves correlating the appearance of stains with the dynamic forces that created them, not predicting every detail of a crime.
- 💧 Passive bloodstain patterns, such as drops, are created by gravity or contact without external forces, and are affected by surface textures.
- 👣 Contact transfer stains occur when a bloody object touches another surface, potentially revealing the source of the blood through the pattern left behind.
- 🏃 Movement can significantly affect bloodstain patterns, creating 'feathering' at crime scenes, which can indicate the direction of movement.
- 🌊 Flow patterns, influenced by gravity, can suggest whether a victim was moved or if their injury was inflicted in a different position than found.
- 🩸 Spatter patterns result from an external force applied to an open source of blood, like striking, and can indicate the direction and angle of the force.
- 🕵️♂️ The process of bloodstain pattern analysis is complex, requiring observation, interpretation, and experience to draw meaningful conclusions from the scene.
Q & A
What is Matthew Steiner's professional certification in the field of forensics?
-Matthew Steiner is a certified Senior Crime Scene Analyst.
Why is safety emphasized when investigating a crime scene?
-Safety is emphasized to protect investigators from bloodborne pathogens and to prevent contamination of the crime scene by their own hair, fibers, and DNA.
What is the purpose of using defibrillated sheep's blood in the demonstration?
-Defibrillated sheep's blood is used because the fibrin, which causes blood to clot, has been removed, preventing clotting and allowing for better visualization of bloodstain patterns.
How does the surface texture affect the appearance of bloodstains?
-Surface texture affects the appearance of bloodstains by altering the edge characteristics, which can be smooth, uniform, scalloped, or spiny depending on the texture of the surface.
What are satellite stains and how do they form?
-Satellite stains are stains that originate from a parent stain and are forced out from the center due to disruption by the surface or when blood is being dripped into blood.
What is a transfer pattern and how can it provide valuable evidence at a crime scene?
-A transfer pattern is a passive pattern created when a bloody surface comes in contact with another surface, potentially leaving an impression of the object, such as a hand, weapon, or clothing, providing direct evidence linking to a suspect.
How does movement affect transfer stain patterns?
-Movement affects transfer stain patterns by creating a feathering effect, which shows the direction of movement and can be identified by the change in darkness from the start to the end of the pattern.
What is the significance of flow patterns in bloodstain analysis?
-Flow patterns indicate the effect of gravity on a volume of blood and can provide insights into the victim's position and movement relative to their injuries at the time the blood was shed.
How can pooling and saturation patterns reveal information about the crime scene?
-Pooling and saturation patterns can indicate the location and duration of bleeding, suggesting that there was a period of time without movement, which can be useful in reconstructing the sequence of events.
What is the process of calculating the area of convergence in bloodstain pattern analysis?
-The area of convergence is calculated by drawing a line through the long axis of several elliptical stains; these lines should converge at the point where the blood originated.
How is the angle of impact determined for bloodstains?
-The angle of impact is determined by measuring the length and width of a bloodstain, dividing the length by the width, and then applying the arc sine function to the result to find the angle.
Outlines
🔍 Introduction to Crime Scene Bloodstain Analysis
Matthew Steiner, a certified Senior Crime Scene Analyst, introduces the topic of bloodstain pattern analysis, emphasizing the importance of safety at crime scenes to protect both investigators and the integrity of the evidence. He explains the use of defibrillated sheep's blood for demonstration, devoid of fibrin to prevent clotting. The video outlines three main categories of blood stains: passive patterns created by gravity or contact, transfer patterns resulting from a bloody surface touching another, and spatter patterns caused by an external force acting on blood. The analysis involves correlating bloodstain patterns with the forces that created them, which is not as instantaneous or exact as often portrayed on TV.
👣 Exploring Passive and Transfer Bloodstain Patterns
The video delves into the analysis of passive bloodstain patterns, such as drops created by blood falling at 90 degrees onto various surfaces, highlighting how surface texture affects the bloodstain's appearance. It also covers transfer patterns, which occur when a bloody object comes into contact with a surface, potentially leaving identifiable impressions. The discussion includes the use of chemicals like luminol or BlueStar to reveal invisible blood traces and the documentation of these patterns for further lab analysis. The segment also touches on how movement can affect transfer patterns, demonstrating 'feathering' effects and the interpretation of drag marks and flow patterns.
💧 Advanced Bloodstain Pattern Analysis Techniques
Matthew demonstrates advanced techniques in bloodstain pattern analysis, focusing on calculating the area of convergence by drawing lines through the long axis of elliptical stains to determine the origin of the blood source. He explains the process of measuring stain dimensions to calculate the angle of impact using the arcsine function. The video also explores how to determine the area of origin using trigonometric principles, considering the three-dimensional aspects of bloodstain patterns. The importance of thorough observation and multiple analytical methods is stressed to ensure accuracy in crime scene investigations.
🕵️♂️ Interpreting Complex Bloodstain Relationships
The final part of the video addresses the interpretation of complex bloodstain relationships at crime scenes, such as the sequence of events indicated by passive stains underneath objects and the direction of travel suggested by blood trails. It discusses wipe patterns, which occur when an object moves through a pre-existing stain, and swipe patterns, which involve blood on a moving object. The video also covers cast-off patterns, which are created by blood flung off a moving object, and void patterns, which result from the interruption of a blood spatter by an object. The segment concludes with a reminder of the complexity and nuance required in bloodstain pattern analysis, emphasizing the need for time, training, and experience.
Mindmap
Keywords
💡Crime Scene Analyst
💡Bloodstain Pattern Analysis
💡Fibrin
💡Passive Patterns
💡Scalloping
💡Satellite Stains
💡Contact Transfer Stains
💡Feathering
💡Flow Patterns
💡Spatter
💡Area of Convergence
Highlights
Matthew Steiner, a certified Senior Crime Scene Analyst, introduces the basics of crime scene forensics.
The importance of safety at crime scenes to protect investigators and avoid contamination.
The use of defibrillated sheep's blood to simulate human blood for training purposes.
Explanation of bloodstain pattern analysis and its limitations compared to TV portrayals.
Demonstration of passive bloodstain patterns created by gravity or contact.
The effect of different surfaces on bloodstain patterns, such as plexiglass, tile, and wood.
Introduction to satellite stains and their significance in bloodstain analysis.
Discussion on contact transfer stains and their value in linking suspects to crime scenes.
The process of creating and analyzing shoe wear impressions in blood.
Impact of movement on transfer stain patterns, such as feathering effects.
Flow patterns and their relevance to understanding injury positions and movements.
Saturation and pooling patterns as indicators of the duration and location of bleeding.
The concept of spatter patterns caused by an external force applied to an open source of blood.
Practical demonstration of impact spatter using a hammer and blood on a wood surface.
Technique for calculating the area of convergence in bloodstain patterns.
Method for determining the angle of impact from the shape of bloodstains.
Explanation of how to calculate the area of origin using trigonometric principles.
Interpretation of bloodstain patterns to understand the sequence of events at a crime scene.
The significance of wipe and swipe patterns in understanding movement through blood at a crime scene.
Identification of cast off patterns and their role in revealing movement of objects through blood.
Void patterns and their importance in crime scene analysis, indicating the presence of objects that were later removed.
Final thoughts on the complexity and interpretive nature of bloodstain pattern analysis.
Transcripts
- There we go.
Hi, I'm Matthew Steiner.
- [Woman] Matt is a certified Senior Crime Scene Analyst.
He's explained crime scene forensics
and technique critique.
- That's a really interesting
yet very illegal way to get DNA from somebody.
- Today I'm gonna show you how to analyze
various bloodstain patterns.
- [Woman] In this episode,
we'll learn the techniques forensics experts use
to investigate bloodstain patterns
ranging from easy to difficult.
- Normally when we go to a crime scene,
it's not set up like this unless we have
some sort of Dexter-esque crime scene
where the killer really planned it out.
Today we're doing it on set for safety purposes.
For us at crime scenes when we investigate them,
safety is number one.
We wanna protect ourselves.
There could be various bloodborne pathogens
that we're dealing with and then secondly,
we don't wanna contaminate the crime scene.
We don't want the hairs and fibers on our cells,
the DNA that's shedding off of us
falling onto our evidence.
At a crime scene, we'd wear multiple layers of gloves
if we're gonna be handling evidence
and then we'd wanna wear eye protection
if there's like a splash hazard
with blood that hasn't been dried.
Our Tyvek suit covers most of our body
including our feet because we don't wanna
be introducing our shoe wear impressions
into a crime scene or destroying evidence that's there.
Normally I'd be wearing a mask,
but I don't think that's a really good look
for talking on camera.
Next, we're gonna talk about the three main categories
of blood stains that we can encounter at a crime scene.
Today we're gonna be using defibrillated sheep's blood.
We have taken the fibrin out of this blood.
Fibrin is a protein that's in our plasma
that causes our blood to clot.
If we used regular whole blood
that had the fibrin in it,
we'd have a clotted mess inside this bottle.
Bloodstain pattern analysts correlate
the appearance of these bloodstain patterns
at a crime scene to a mechanism
by which they were created.
It isn't a crystal ball.
It isn't like the way TV presents it
where a crime scene investigator walks into a scene
and can tell you every single action
that happened inside that crime scene
from beginning to end.
Analysts can correlate the static bloodstains
at a crime scene with dynamic forces that create them.
So we look at is specific stain patterns
and we can figure out how they possibly were created
and then with that, we could show a small window of time.
Not the whole crime, but this type of force
could have created this sort of pattern.
Passive patterns are patterns that are created
without any sort of outside external force
other than gravity or contact.
We're gonna first start off with dropping blood
at 90 degrees to see what we get.
I'm going to take pipet
and a small amount of blood
and hold it directly above and drop it.
When our sphere of blood strikes a surface at 90 degrees,
we have a very even, round circle at a crime scene.
But also what affects the way our bloodstain looks
is the surface itself.
We have plexiglass and we notice that
the edge characteristics of our bloodstain
are very even.
Now that we observe the way that blood acts
on a smooth surface, let's try tile
which has a little bit of texture to it.
One drop of blood straight down
onto a different surface now.
You can see a little bit of scalloping
around the edges there.
That's because of the surface texture.
The scalloping is just different ways
that we describe the edge characteristics of bloodstains
so it could be smooth, uniform, it could be scalloped,
or it could be spiny.
Now we change the surface to a rougher surface, wood.
We can see a vast difference from where we started
where we have smooth edge characteristics.
Now we have the spinier pattern
because that blood drop is being disrupted
by the surface itself.
And we could also see we have some satellite stains.
Satellite stains are stains that come off a parent stain,
so this main stain here is my parent stain.
In this case because of the disruption,
they are being forced out from the center of it.
We also see satellite spatter when blood is being
dripped into blood.
Typically at a crime scene,
especially with stabbings,
we wanna look for these drip patterns.
It could be that the suspect accidentally cuts themselves
and they're moving around a crime scene
and they're fleeing the crime scene
and they could leave blood trails that we could follow.
Next we're gonna be looking at contact transfer stains.
A transfer pattern is a passive pattern
where we have a bloody surface
coming in contact with another surface
and then sometimes we could actually figure out
what made that transfer whether it was a hand
or a weapon or someone's clothing.
That's the best type of evidence
that we could have at a crime scene.
We have the victim's blood
and we have the suspect's impression.
There's very few explanations of how that happens.
We're gonna start off with a shoe wear impression in blood.
This could be our victim walking through blood,
creating patterns in our crime scene,
or this could be the suspect's shoe wear impression.
We're gonna coat the bottom of the shoe
and we're gonna transfer the pattern
of the bottom of the shoe to our clean surface.
I have my shoe wear that's completely coated in blood
and then inside that crime scene,
we have a transfer of that pattern
and we'll notice is that that pattern
gets lighter and lighter as we move along.
What we don't see with our naked eye
we could find later on with chemicals
like luminol or BlueStar.
We could see a continuation of that pattern
as someone walks away from a crime scene.
Sometimes we see transfer patterns in textiles.
Next we're gonna take some blood,
saturate a portion of our jeans with it
and we're gonna transfer that onto our surface.
Sometimes in real crime scenes,
these get misinterpreted as the lines that move from
your fingerprints or palm print.
What we see is that unlike fingerprints,
they're just straight lines.
Either way, we would document this and collect it
and send it to the lab and then under magnification,
analyze it.
Next we're gonna discuss how movement
could affect these transfer stain patterns.
I'm gonna take some blood and put it on my hand
and then move that across the surface.
So if I touch this surface and then move my hand,
we see what's called feathering,
the effect of movement on blood
just like if I took a paint brush
and moved it across a wall.
In the beginning it would be darker,
but eventually it would get lighter.
- This feathering affect helps us interpret
movement at a crime scene.
This could be found at a crime scene in many different ways.
One could be our suspect has blood on her hands
and they move it across a clean surface
and another very common way that we see
these patterns at a crime scene
are what's called drag marks.
We have a victim that's bleeding
and either they're moving through the scene
or someone's dragging them through the scene
and we'd see the same effect,
that feathering going towards the body.
Next we're gonna cover flow patterns
and that is a volume of blood
being affected by gravity.
So what we can see here is that gravity
is pulling upon that blood
and pulling it down on our surface.
At crime scenes, this may be very valuable evidence
when we observe our victim's injuries.
A person had an injury to their shoulder.
If they're standing or if their body is erect,
that flow pattern should go straight down their arm
but if they've been moved or there's movement
or that injury was caused when they were laying down,
we'd see a different flow pattern.
Next we're gonna discuss saturation
and pooling patterns that we'd have at a crime scene.
Saturation and pooling patterns
could tell us that someone is bleeding
at a certain part in a crime scene
for a period of time.
Sometimes when we see bubbles at a scene,
that could mean that we have an expiated pattern
or a pattern that's coming from an airway
but let's pop those because we don't want.
What this could tell me is that
we had accumulation of blood there
and that there has been no movement
because if this happened
and then we moved the shirt,
we would see that the blood would move in that direction.
Typically we'll see this on mattresses
or beds or bedding and then it would absorb
a little more.
Now we're gonna have an accumulation of blood
on a non porus surface and we'll see pooling.
Pooling and saturation, it's the same mechanism
that we'll looking at,
just accumulation of blood.
But with pooling, the blood is not being absorbed
into the surface.
For pools of blood what we'll see with actual whole blood
that has fibrin in it, they will dry a lot slower
than it would in something that's absorbent,
but also we're gonna see over a period of time
is clotting inside that pool.
And then sometimes we'll see effect what's called
serum separation, so the edges of this would be clear
where we'd see the plasma of the blood
as it separates.
Now we're moving onto the spatter category
of bloodstain pattern analysis.
With this category of bloodstains,
we're looking at some sort of external force
on an open source of blood.
So what I'm gonna do is I'm gonna put
a small amount of blood on our wood here,
I'm gonna strike it with a hammer
and then what we should see is that impact spatter
on the plexiglass in front of us.
Put on my googles,
I'm gonna put my hood up.
Get us a small amount of blood here.
All right, ready?
There we go.
So as you can see [laughing]
not only do we have impact spatter
on the plexiglass in front of us.
We also have it on our suspect here.
We applied force to an open source of blood
and we have a resulting impact stain.
Our stain pattern, what we will notice is
directly opposite where the force was applied
we have our blood striking that surface at 90 degrees.
These stains that we have right here
near the bottom are circular
but the further we move away from that source,
these bloodstains are now hitting this surface
at an angle so our stains are more elliptical.
Bludgeoning would be the most common way
that we get these stains
but it could be that we have
the force of a bullet passing through somebody,
so we have a phenomenon called forward spatter
and back spatter.
So if someone is shot and the bullet
passes through say their shoulder,
we have blood going in the direction of the force,
so with the bullet out of the exit,
but we also have blood going the opposition of the force,
and that's what we call back spatter.
First off we started by creating different patterns
so that we could analyze.
Next step, we're gonna at something a little more difficult.
Next we do is calculate the area of convergence.
That's the two dimensional area on our surface.
If we draw a line through the long axis
of several stains where all these lines will meet.
They should converge in an area
somewhere in the center here.
What I wanna do is pick several stains
that are elliptical from different sides of the pattern.
We're looking at this to solve where this blood came from.
I'm gonna start with this stain here
and I'm going to line up so that I'm drawing
a line through the long axis of my stain.
So this is where the tail is gonna help me out
to figure out the directionality,
but also to line up my ruler.
And then sometimes what we'll do
is just kind of show for a jury an arrow,
the direction that stain was going.
Then I'll move around a pattern from different sides of it
and draw through different stains.
This isn't done on every crime scene but when we have
a pattern like this that we have elliptical stains
along the outside and we have some
circular stains towards the inside,
this is the perfect opportunity
for us to do some analysis.
I could keep going and draw more lines
for more stains and it should all be coming back
to the same general direction.
If this was on the wall
and this was very low,
this could be very powerful evidence
to show that that was low to the ground
where this impact happened.
Since we identified different stains
that are striking our surface at different angles,
we're gonna figure out the angle of impact
that these stains hit our surface.
We do that by measuring the length of the stain,
we divide it into the width of the stain
and the arc sin of that number
will give us our angle of impact.
So when we're measuring stains,
we always wanna use millimeters.
Allows us for smaller measurements
so what we could also use is a digital caliper
and that will give us precise,
sub millimeter measurements.
So I wanna measure the length of the stain,
long axis of the stain, so this is 3.1 millimeters.
And then I'd measure the width of it
so I'm measuring the widest part of the stain.
That's 1.7 millimeters.
We're gonna divide 3.1 into 1.7
so if we do the arc sin of that number,
that'll give us the angle of impact,
which is 33.25.
If you had a regular ruler,
you would just have to round up to
the closest millimeter, so in this case,
this stain is four millimeters,
and then we'd measure the width of it.
It is two millimeters.
So we would divide four into two
which gives us .5 and the arc sin of .5 is 30 degrees.
And we can see this basically at the same distance
from our center, but just on the other side.
If we look at this two dimensionally,
we know that these lines of our area of convergence
meet here but if we wanna think about it
three dimensionally that my blood is coming from
somewhere above it here.
The next step will be that we're gonna
calculate the area of origin.
If it's coming at a right angle here,
I have a triangle.
So this would be my adjacent side of the triangle.
I know that it's 90 degrees from here,
so that's my right triangle
and then this side that the path takes
is the hypotenuse of the triangle
and so if I know the distance from my stain
to my area of convergence
and I wanna figure out how far away
my area of origin is here in space,
if I do the tangent of that,
I could figure out the side, like sohcahtoa.
When we analyze bloodstains in the field,
I always feel it's better to do all these methods.
We should coming out with similar results
but if you messed up somewhere,
one of those is gonna be correct.
Next up we're gonna try something
a little more difficult, interpreting relationships.
There's an adage that forensic science
is the art of observation governed by science.
So we have observed our stain patterns at our crime scene
and we're gonna interpret how these possibly were created.
If I go to a crime scene and I see that
there's some clothing there,
eventually I'm gonna recover this,
but after I recover it and I see that
there's passive stains underneath it,
I know that this came after this.
That this wasn't in place,
that this was placed afterwards
and if I don't see a transfer of blood on here,
it could be that this was already dry
by the time this clothing went on top of it.
Now we're looking at a passive drip pattern.
This could be the victim's blood,
this could be the suspect's blood.
We won't know until we sample it
and send it off for analysis.
What we can interpret from this could be movement.
So if this trail of blood is leading away from the scene,
we would see those tails going in a direction of travel.
Now we're looking at a wipe pattern.
We have a pre-existing stain that something
came in contact and moved through it.
So we could see from our discussion earlier of feathering
that the directionality is coming towards me.
Something is passively dripping blood.
That could be a weapon, that could be a victim,
that could be our suspect
and then something later on comes through it.
That could be someone trying to clean up the stain.
This could also be that maybe someone
was dragged through this or there was
some sort of movement through that stain.
That was a wipe pattern, now we have a swipe pattern.
Blood is on something here and we can see that again
that same feathering going in the direction of travel.
We have a transfer pattern with movement
which is a swipe pattern.
There's blood on something
and then we're just moving that in a direction.
Usually when it's a wipe pattern,
we could see those original stains,
so they're drying and then someone tries to
wipe them off with a cloth.
Now we're looking at a cast off pattern,
so this is a sub-category of spatter
that's a projection mechanism,
so blood is on an object and we're moving
that object in space.
That could be someone's hand,
that could be a pipe,
that could be a bat, that could be a knife
and as that object moves,
blood will be flung off it
and we have these very distinct linear patterns
or curvy linear patterns.
At a crime scene if we see these cast off patterns,
they can go up the walls,
they can go across the floor
and even onto the ceiling.
We're looking at a spatter pattern,
but we have a normally continuous drops of blood
that are being interrupted
or blocked by something and that gives us
a pattern that's called the void.
Sometimes we have crime scenes where
there's something important
that would be in that pool or in that pattern
or that spatter pattern and it's been removed.
So it could be someone's bag
or a cell phone, their wallet.
I had a crime scene where someone was bludgeoned
and adjacent to his head was the complete absence
of blood spatter.
Looking to the left of him,
there was a spatter pattern that didn't line up.
What we determined was that the curtains
inside of the hotel room were open
at the time of the crime and then closed later on.
We've gone over how these patterns are created,
our different categories of patterns
and what we can interpret from these patterns
at a crime scene.
This is not a simple process.
This stuff takes time, training, and experience
and beyond that, there's no absolutes with any of this.
There's no one specific answer
then it's only that one answer.
I hope you guys learned a lot.
[applauding]
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