ECSE6963, BMED 6961 Cell

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Title: ECSE6963, BMED 6961 Cell

1
ECSE-6963, BMED 6961Cell Tissue Image Analysis

Lecture 5 3-D Multi-Spectral Microscopy
Badri Roysam
Rensselaer Polytechnic Institute, Troy, New York
12180.

2
Important Announcement!

On Monday, Sept 15th, I will be at a conference.
Here is a link if you are curious
http//www.hhmi.org/janelia/conf-021.html
computer vision image analysis are closely
related fields
Voice-annotated lectures will be on the course
website
Please download and play them on a computer with
sound turned on (just type F5)
Save your questions until our Sept 18th class

3
Recap

3-D Scanning Microscopy
The multi-photon effect is a powerful basis for
3-D imaging
Second Harmonic Generation Imaging (SHG) is a
lossless kind of multi-photon microscopy for many
molecules (e.g., collagen)
Fluorescent Proteins and multi-photon is a
magical combination that allows live-cell imaging
Confocal Microscopy can do 3-D microscopy without
the multi-photon effect
Significantly improves z-axis resolution (axial
resolution) compared to ordinary widefield
microscope
Today
Multi-Spectral Imaging (for fluorescence
multiplexing)

4
Faster Confocals

Spinning Disk Systems
Nipkow Disks
Scans lots of points at once using a rotating
disk with a spiral array of holes, and a CCD
camera instead of photomultipler tubes
The basis for all modern high-throughput
microscopes

5
Multi-Spectral Imaging

Basic Motivation
How can we capture multiple fluors at once?
Fluorescence multiplexing
We want to capture the relative spatial context
of two or more fluorescently labeled structures
Solution
Build instruments that allow us to adjust two
things in unison
the excitation wavelengths
Put a filter wheel in front of a broadband source
to select illumination wavelengths
Use multiple and/or tunable light sources
the wavelengths that our detector is sensitive to
(spectrally resolved detection)
Use optical filter wheels in front of detectors
Use a prism or a diffraction grating to split the
detected beam, and an array of light detectors

Array of detectors
6
5-D Multi-photon Microscope
Image Acquisition Control Computer
Image Signal
PMT Gain Controls
Wavelength Control
Pulsed fs Ti-Sapphire Laser
PMT 1
PMT 2
PMT 3
PMT 4
Power Control
Mirror
Power Attenuator
Visible Emission Light
Sync Signal
560nm
495nm
515nm
Resonant Scanning Mirrors
Short pass dichroic
Long-pass dichroics (typical wave length cutoffs)
Near-IR Excitation Light
Objective Lens
Piezo Z control
Specimen
7
(No Transcript)
8
The Zeiss META System
Diffraction Grating
Detector Array

The fluorescence light after the pinhole is
passed through a grating to an array of 32
detectors (PMTs)
Produces a lambda stack I(x, y, z, ?)
A spectrum at each pixel!

9
5-Label Immunohistochemistry

Nuclei
Blood vessels (EBA)
Neurons (Nissl)
Astrocytes (GFAP)
Microglia (Iba1)

Excitation spectra
Emission spectra
50 ?m
10
5-Label Immunohistochemistry

Nuclei
Blood vessels (EBA)
Neurons (Nissl)
Astrocytes (GFAP)
Microglia (Iba1)

Excitation spectra
Emission spectra
50 ?m
11
Dealing with Overlapping Spectra
1
2
Nucleus histone GFP Fusion Actin filaments
fluorescein conjugated phalloidin The peaks are
separated by only 7nm !
12
Dealing with Overlapping Spectra
Reference Spectra
Unmixing Result A1 and A2
Compute A1 and A2 at each pixel subject to
constraint A1 A2 1
13
Ultimate Optical Microscope of the Future

Isotropic and high-resolution sampling of 3-D
space (x, y, z)
Recent microscopes have broken past the Rayleigh
resolution limit
No wasted photons 100 detection
Recent microscopes perform 4 pi imaging
Complete spectrum at each pixel
Measure absorption emission spectrum
Complete flexibility to shape the excitation
spectrum
Complete flexibility to capture and analyze the
emission spectrum
Complete lifetime response at each pixel
Photon counting hardware at each detector
Time response at different spectral wavelengths
Multiple modalities looking at the same specimen
One of the holy grails that continues to be
pursued

14
Recap Image data

2D image I(x, y)
Matrix of point measurements
Point pixel
Pixels have
Size ?x, ?y
Non-isotropic images ?x ? ?y
Dynamic range 2N
3D image I(x, y, z)
Point voxel
Axial extent ?z
Image sequence I(x, y, z, t)
Time sequence of 2D/3D images
Temporal interval ?t
Multi-spectral image I(x, y, z, ?)
Each pixel/voxel is vector valued
Each element spectral band
Multi-modal image I(x, y, z, c)
Each pixel/voxel is vector valued
Each element imaging modality

Pixel intensity
15
Image Files Metadata

Some practical issues
The file is a linear data structure
We need to pay attention to how the
multi-dimensional data is expanded into a linear
array
Need to know the bit ordering within each data
point
Meta data data about the image data
Usually stored in the file header
Currently, image file headers can be quite
elaborate
They can store information on where the data came
from (provenance), microscope settings user to
record the image, etc.
TIFF allows a free text field in the header where
one can store additional information
OME TIFF uses XML file formats
Lots of tools available to convert between file
formats, viewing images, etc.
For our purposes ImageJ MATLAB are adequate.

Header
Image Data
16
Quantitative Image Analysis

The process of generating measurements of
biological interest from image data
Can be thought of as the generation of additional
metadata
Nature of measurements
We are interested in measurements at the level of
objects, and groups of objects, rather than at
the level of pixels
Objects usually correspond to biologically
meaningful entities
Implies that we need to extract objects from
images first!
This is the hardest task, the rest is much easier.

17
Steps From Images to Insight

Step 1 Image pre-processing
Cleanup image data (suppress imaging artifacts)
Unmix the data into channels
Step 2 Delineate objects (segmentation)
Accurately delineate all valid objects, reject
invalid objects
Step 3 Validation Morphometry
Correct segmentation errors
Compute intrinsic object measurements
Step 4 Object classification
Step 5 Associative object measurements
Step 6 Statistical Graphical analysis
Concise, insightful summary

Very Important!!
18
Recap Reasons to Prefer Fluorescence Imaging

Simplicity
Assuming that we our fluorescent label is
specific enough, we can image a specific
substance, structure, or a class of substances/
structures selectively
Images only show these labeled things
Bright pixels tell us where the structures of
interest are, and dark pixels are background
Multiplexing
You can use multiple fluorescent labels to image
several related things simultaneously
Helps us to measure relationships among objects

19
Common Object Morphologies in Fluorescence Images
F
Foci on Barrier
M
Plate / Barrier
P
Foci in ECM
Extra-cellular matrix
F
C
Tube-associated Foci
Neurites
Nuclear membrane
F
T
Cytoskeleton
S
C
Nucleus
Cell membrane
B
Intra-nuclear foci
S
Cytoplasmic foci
F
F
Microvasculature
T
20
Pure Channels

Channel
The image data from each fluorescent label (or
imaging modality) is commonly referred to as a
channel
Pure Channel
A channel is considered pure if it only
contains one type of object
The fluorescent label is sufficiently specific to
the object
There is negligible spectral overlap (cross
talk)
Major advantages
Software for making measurements is much
simplified
Specialized segmentation algorithms for each type
of object can be much simpler since they only
need to be able to handle one object type
High-performance software possible
We can exploit the specialization to develop
highly reliable segmentation algorithms

21
Impure Channels

There are basically two kinds of impurities to
consider
Case 1 Morphologically impure
The fluorescent label is not specific enough
We can get two or more types of things in a
channel
Solution 1 (preferred) work with the biologist
to either choose different things to label, or
different labels if at all possible
Solution 2 develop algorithms that can handle
morphologically mixed data
Case 2 Spectrally impure
The fluorescent labels are specific, but their
spectra overlap heavily
Solution 1 (preferred) seek out alternative
fluorescent labels
Solution 2 computationally unmix the data

22
Example from Neuroscience Research

The niche (microenvironment) in which adult
neural stem cells live
A Complex Dynamic System
Multiple interacting cell types
3-D vascular relationships
3-D Spatial polarity
Axes of asymmetry for divisions
Lineage relationships
Multiple molecules of interest
Signaling relationships
Transport phenomena
Molecular gradients
Cell migration dynamics
Gene regulation mechanisms

Ependymal
Immature Precursor
Migrating Neuroblasts
Astrocyte
B
C
A
GFAP- Dlx2 LeX
GFAP- Dlx2 PSA-NCAM
GFAP LeX
23
4-Color Imaging of the Adult Neural Stem-Cell
Niche
Collaboration Sally Temple (AMC)
24
Segmentation

Goal
Label each pixel/voxel as belonging to a specific
biological object, or part thereof
e.g., surface of cell nucleus 30
Comments
Establishes a higher level of abstraction for
further image analysis
The hardest step
Tries to mimic our visual system
Depends on the nature of the object(s) in the
image
Morphology, appearance, expected distortions
Model based image segmentation algorithms
generally the most effective

25
Segmentation methods

Manual / computer assisted
Use the pattern recognition abilities of the
human visual system
Still unbeatable!
Use a computer to record data
Great for small-scale image analysis
Tedious, costly, and impractical for large-scale
Subjectivity is a problem
Multi-observer analysis can help
Limited by hand unsteadiness attention span
Automated systems much better
Limited 3D capability
Stereo viewing is the best you can do

26
Tricks to make manual analysis practical

Randomly subsample the image extrapolate to the
full data
unbiased stereology
Defines methodical ways to minimize bias
Big user community
Software packages available
Drawbacks
Variance can be high
Assumes tissue is homogeneous
Advocates extraction of small numbers of
measurements from large numbers of animals
Cannot handle multi-dimensional data
Bottom line
Manual analysis is good for small-scale studies
Automated methods have much more to offer
They can also be used in conjunction with
stereology

27
How we treat the objects we segment

Compartments
Usually defined by cell/tissue structures
A compartment is a region of space occupied by
the structure of interest
One compartment can be included in another
Surfaces
Think of them as membranes
Usually separate two or more compartments
Functional Signals
Mobile molecules of interest
Do not define a region of space
Usually indicate an activity of interest,
either directly or indirectly
Biologist must specify how each channel must be
interpreted, and what it contains
Compartment / surface / functional signal
What kind of shape

28
Divide-and-Conquer Strategy
Blob Segmentation
Tube Segmentation
Compartments
Compute Associations
Shell Segmentation
Output
Un-mixing
Microscopy Data
Plate Segmentation
Surfaces
Man-made Objects
Signals
Foci Segmentation
Cloud Segmentation
Pure Channels (common case)
Morphological Unmixing
Mixed Channels (rare case)
29
Basic Types of Measurements

Intrinsic Measurements
These measurements are specific to each type of
thing
Associative measurements
These measurements are based on associations
between one or more of these things

30
Channel 1 pure Fluorescent label DAPI Molecule
of interest Nuclear DNA Type of thing
compartment Compartment Morphology Blobs
DAPI
Blobs
31
Intrinsic Blob Measurements

Measures of Location
x, y, and z of centroid
Measures of size
Volume, diameter
Measures of shape
Eccentricity, shape factor, irregularity
Measures of appearance
Average brightness, texture

32
Channel 4 pure Fluorescent label Alexa
546 Molecule of interest Lewis-X a carbohydrate
found in the extra-cellular matrix surrounding
neural stem cells A functional signal Type of
thing Irregular Cloud
Alexa 546
Clouds
33
Intrinsic Cloud Measurements

Measurements of signal strength
Brightness
Intensity per unit volume
Measurements of variation and organization
Brightness variance
Texture and flow
Measures of size
Volume, diameter
Measures of shape
Spatial compactness
Stellateness

34
Channel 2 Morphologically spectrally impure!
Fluorescent label Alexa 647 (Cy5) Molecule of
interest laminin that forms the basal lamina
of blood vessels. Compartment type Hollow
Tube Comment Laminin is also part of another
structure (bulbs)
Tubes
Alexa 647 (Cy5)
Shadows of Nuclei
Blobs
35
Bulbs
Traces
Rejected
36
Channel 3 Morphologically impure! Fluorescent
label Alexa 488 Molecule of interest GFAP
(glial fibrillary acidic protein) Compartment
type Tube Comment GFAP also found in soma of
cells
Soma
Alexa 488
Tubes
37
Traces
38
Intrinsic Tube Measurements

Measurements of Location
(x, y, z) locations of centerlines
Locations of branch points
Metric Measurements
Thickness (diameter) at each location
Curvature
Tortuosity (curvature change per unit length)
Topological Measurements
Branching frequency as a function of branching
order

39
Associative Measurements
Association (1, 2) ltList of Associative
Measurements gt
Object 1 ltList of intrinsic featuresgt
Object 2 ltList of intrinsic featuresgt

Quantify relationships between segmented objects
Numerous associations can be imagined
Even the simplest of these are immediately useful
Examples
Proximity, orientation, connectivity
Adjacency and Neighborhood relationships
Marker-based object classification
e.g., Tracking change analysis
Can be summarized in familiar ways
e.g., Time course / dose response / Spatial
Variations
Conditional histograms and distributions

40
Associative Measurements are a General Concept

For a fixed point in time
Establish associations between compartments,
surfaces, and functional signals
Each association leads to a measurement of signal
localization, structural relationships, etc.
Across points in time
We first need to track compartments, surfaces,
and signals over time
Measuring changes for tracked objects over time
yield measurements of dynamic phenomena such as
morphological dynamics, molecular transport,
signaling, cell movement,

Time
41
Associative Measurements for Blobs

Signal Associations
Measure the amount of signal in another channel
relative to each blob
Within the blob volume
On the surface
Within a defined distance around the blob
Spatial Associations
Measure the location of the blob relative to
other things
Other blobs, tubes, plates, man-made
structures,etc.
Spatio-temporal Associations
Track the movements of blobs over time

42
Example
43
Cell-Cell Adjacency Features

Computed by associating cytoplasmic labels with
nearest nucleus, and segmenting the space
associated with each nucleus
Number of neighbors that are in contact
Contact areas between neighbors
Number of membrane/other barriers and their
signal strength
Spatial organization patterns

44
Tube-Cell Associative Features

Computed by associating nuclei and associated
structures with nearest tube
Distances to nearest tube
Center distance or surface distance
Analysis by branching order of tube

45
Associating Nuclei Vessels

Draw a perpendicular line to nearest vessel
segment for each segmented nucleus, and measure
its length.

46
Cell Network analysis

Computed by associating nuclei with nearest other
nuclei
Distances to nearest neighbor
Integrate secondary label(s) along the path from
one nucleus to the other
Yields a labeled graph structure
Nodes cells
Arcs relationships

47
Putting it all Together
48
Sample Table of Measurements
3D Location
Distance to Vessel
Eccentricity
Nuclear ID
Convexity
Intensity
Gradient
Texture
Laminin
Lewis-X
Volume
Shape
GFAP
Collaboration Sally Temple (AMC)
49
Example Plot
50
Summary

Basic Steps and Image Analysis Terminology
Divide Conquer Segmentation
Fluorescence imaging simplifies image analysis by
enabling a divide and conquer strategy
Pure channel One channel, one morphology
Basic Types of Measurements
Intrinsic one set for each channel
Associative relates objects across channels
Next Class
Well follow the divide and conquer road map from
here on, starting with
Blob segmentation methods

51
Homework - Part I

1. Using the formulas described today, calculate
the best-achievable lateral (x - y) resolution
and the axial (z) resolution of a microscope with
a numerical aperture of 0.9, at a wavelength of
550nm, and a water immersion medium
The axial direction is along the optical axis,
and the lateral direction is perpendicular to it.
Along which direction does the microscope have
poorer resolution and by how much?
Describe at least 3 potential methods to improve
the axial resolution, and discuss their
limitations
2. The Chameleon Titanium-sapphire laser from
Coherent Inc. (http//www.coherent.com/Downloads/A
CF12E4.pdf) is widely used for multi-photon
imaging.
If this laser is delivering 1 watt of energy at
a pulse repetition rate of 90 MHz, how many
joules of energy does it deliver in each pulse?
(1 watt 1 Joule/sec, 1MHz 1 million/sec)
If the duration of a pulse is 140 femtoseconds
(1 femtosecond 10-15 secs), what is the wattage
during the pulse?
If the above excitation is concentrated on a
cube of side 0.2??m in the specimen (1 ?m
10-6m), calculate the number of watts per cubic
micrometer that we are applying.

52
Homework Part II

3. Download the image AVO20429_03ah that was
obtained with a Zeiss LSM META microscope, from
the course web page
This is a compressed zip file, so you need to
unpack it first
Explore the different ImageJ viewing options, and
options for data import/export on this software
Make sure you can see an x-y, x-z, and y-z cut
through the data
Make sure that you can visualize each channel by
itself
4. Answer the following questions
What the size of the image in the x, y, and z
dimensions?
How many channels does it contain?
What can you say about the shapes of objects in
each channel?
See any diversity of shapes within a channel?