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Introduction to basic concepts and methods of modern stereology
Goran Šimić, CIBR, 21th Apr 2006.
Contents
I. What is stereology?
II. Basic concepts of modern stereology
III. Most commonly used stereological methods
IV. Advices and examples
I. What is stereology?
Stereology is a statistical methodology for estimating the geometrical quantities of an object such as number, length, profile area, surface area, and volume
In practice, stereology is a "toolbox" of efficient methods for obtaining unbiased
3D-nal information from measurements made on 2D microscope sections
Stereology is now recognized to be of major value in science and medicine
Origins and applications
Developed by materials scientists, mathematicians, and biologists since early 1960sFlourished in late 1980s and early 1990sCan be applied to all biological structures
Why is stereology better than the “classical morphometry”?
Focuses on total parameters (e.g., total cell number) not densitiesAvoids all known sources of methodological biases (e.g., assumption that a cell is a sphere, split cells and “lost caps” )Avoids inappropriate correction formulas
However, tissue processing requirements differ from assumption-based methods (probes, i.e. sections should be IUR = isotropic and uniformly random). Such sections are usually unusable for routine qualitative analysis (e.g. cortical sections)
A histological section is a biased sample of particles
In a stack of serial sections, relatively taller cells are represented on relatively more sections. If we chooseIn contrast to classical (old) quantitative methods, new (modern) stereological methods avoid this bias
II. Some basic concepts of modern stereology
1. Estimation / sampling
2. Accuracy / unbiasedness
3. “Significance”
4. Explanation of results obtained
1. Estimation
Usually, we cannot “determine” the value of a parameter unless we exhaustively sample the entire material.
Instead, we infer the parameter value from a sample, subject to random error – this is statistical estimation.
Variance is a random fluctuation between data values or between successive repetitions of the experiment
Basic definitionsPopulation: a well defined set of elements (“sampling units”) about which we want to make inferences
Example 1: All Croatian adults (discrete population)Example 2: Brain of rat no. 179 (continuous population)Example 3: Brains of 25-day-old male Wistar rats (superpopulation)
Parameter: a well defined numerical quantity relating to the population
Example 1: Average height of Croatian adultsExample 2: Total brain volume of rat no. 179Example 3: Average total neuron volume of 25-day-old male Wistar rat
Sample: a set of individuals taken from the populationExample 1: Ivo Ivić and Pero PerićExample 2: Twenty sections from brain of rat no. 179Example 3: Brains from 25-day-old male Wistar rats
Uniform sampling: a mechanism for choosing samples randomly so that every sampling unit in the population has the same probability of being selected for the sample
Population and sampleAlways keep in mind the distinction between population and sample
“The sample looks like the population”:- If it is correctly sampled- If it is large enough
Issues:
- How do I take a “representative” sample?- How do I get unbiased estimates of population parameters?- How precise are these estimates?- What is an optimal sampling design?
Sampling
Estimates should refer to a biologically meaningful reference spaces in a defined population
Sampling should be representative i.e. uniform random (every member of the population needs to have an equal chance of being selected for the sample)
Requires that the structure of interest can be unambiguously defined
The “reducing fraction” problem of sampling
The effect of increasing magnification decreases the proportion of the original object being sampled
Hierarchical nature of sampling for microscopy
Uniform random sampling should be employed at every level of the sampling hierarchy (in other words: At no stage should anything within the defined reference space be ‘chosen’)Use nomograms to spare time (Gundersen and Jensen, 1987; Gundersen, 1999)
Sampling can be optimized formaximum efficiency ("Do More Less Well").
In a typical biological experiment the overall observed variance (the “spread” of a distribution around its mean) consists of the following relative components:
Message: Concentrating on making very precize individual measurements will at best only increase the precision of the overall experiment by about 2%!
70% inter-individual (biological)
20% between blocks
5% between sections
3% between fields
2% between meas.
Sampling can be biasedAn illustration of how the moving averages of an unbiased estimator of N behave as an experiment is replicated
The magnitude of the bias B is unknown = totally invisible at the end of an experiment (you simply have a numerical estimate and there is no way to determine bias from your data!)
The presence or absence of bias depends mostly upon the experimental or sampling method used
Systematic error = bias
Bias is the differencebetween the expectedvalue of an estimatorand the true parametervalueSources of bias:- Wrong calibration- Observer effects- Incorrect assumptions- Wrong sampling,- Any type of selection
Biases do not cancel each other
It is often argued that biased measurements may be used when we want to compare two experimental groups.
However, this is only justified if the bias in both cases is equal (what we usually just don’t know)
Unbiased sampling regimes
Independent random sampling (randomly generates a sample of fixed size)
Systematic random sampling (samples a fixed proportion 1/m of total population; starts at random and count every mth item; the sampling probability is 1/m)
Cluster sampling (after grouping items into arbitrary “clusters”, use an unbiased sampling method to select some of the clusters)
Stratified random sampling (divide the population into subpopulations or strata and sample every stratum by an unbiased sampling rule)
2. Accuracy / unbiasedness
Accuracy cannot be ‘bought’ by working harder: Accuracy can only be guaranteed by using ‘tools’ (methods) that are inherently unbiasedIn stereology this means start with the uniform random sampling that is followed by the application of a set of unbiased ‘geometrical questions’ in 3D (probes)The a priori guarantee of accuracy of these methods, without the need for validation studies, is a major advantage: They can literary be ‘taken off the shelf’ and used in any situation!
Do not mix accuracy (unbiasedness) with efficiency (precision)
It is possible to have a biased estimator which is ‘efficient’ (converges on to a stable value quickly and has small SD), as well as inefficient unbiased estimator
Only if you know that you have an unbiased estimator,you can use variance or SD to measure precision.
Low variability
High variability
Factors contributing to variance
Instrument noise
Sampling variation
Biological variation
Dependence on uncontrolled factors
Oberver effects (counting errors), etc.
Variance can be estimated empirically, but is unrelated to bias.
Random error can be decreased by taking more data; bias willnot decrease. So, it is important to minimize bias of estimators.
3. “Significance”
“My two experimental groups gave different results. Does this prove they are different, or is it just the result of random variation?”
Use: - regressions
- formal significance tests for H0
- other statistical methods
4. Explanation Try to attribute variability to different factors (sources of variability) such as:
- Age- Gender- Different experimental conditions, etc....
Analyze response variables vs. explanatory variables
Analyze systematic effects vs. random effects
ExampleExplain brain weight of rat as combination of several influences:
Weight = population mean + litter effect + indiv. variation
Rats from the same litter differ less than rats from diff. litters
Var(weights) = Var (litter effects) + Var (indiv. deviations)
Estimate this from all rats
Estimate this by comparing litter means
Estimate this by comparing rats within a litter
III. Some of the most commonly used stereological methods
1. Cavalieri principle for volume estimation
2. Physical disector for number estimation
3. Optical disector for number estimation
4. Optical fractionator for number estimation
1. Estimation of reference volume using the Cavalieri method
V= t . A(p) . Pt=average slab thickness =distance between section planesA(p)=area per test point corrected for magnificationP=total number of test-points hitting the structure
Tissue shrinkage
Due to dehydration and embeddingDifferential shrinkage must be calculated (for the 3rd dimension, use the sqare root of the calculated areal shrinkage)Final volume can be only 26% of original (fetal brain has higher % of water) (Pakkenberg, 1966)
Stereological probes
Feature = geom. feature of a 3D object to which the probe is sensitive
d = n – k
d = feature dimensionn = dimension in which objects are embeddedk = dimension of a probe
Only if d=n or k=n, the distribution of estimated objects is irrelevant
The unbiased brick counting rule for number estimation (Howard et al., 1985)
Inclusion planes (surfaces)
A particle is counted if it is totally inside the brick or if it intersectsany of the acceptance (inclusion) planes and does not intersectany of the forbidden surfaces anywhere.
The unbiased brick counting rule is ageneral 3D counting rule that is applicablefor particles of any shape and size.If the particles of interest are convex, suchas nerve cell nuclei, then the opticaldisector can be used (Gundersen, 1986).
Optical disector(about 5x faster than
physical)a) Not counted
(topmost plane is exclusion plane)
b) Is counted (nucleus touches the inclusion line)
c) Not counted (cuts the forbidden line)
d) Profile is sampled
e) and f) are counted (bottom plane is inclusive)
Dark nuclei are in maximal focus
Fractionator principle (2D example)
Optical fractionator (3D)
Outline a region of interest at a low magnification. The region may encompass several fields of view.Once a region of interest has been defined, count cells at high power.The image on the right shows a counting frame for an optical fractionator probe superimposed on a live video image.
Optical fractionator (3D)
The overall fraction of the object sampled = ssf . asf . hsfTotal number of particles in the object = Q . 1/hsf . 1/asf . 1/ssf
Scheme of themulti-stage fractionator
Example of a local probe
Local probes may be integrated with global probes to measure the size of objects as they are counted. Here a nucleator is being used with an optical fractionator to measure cell area and volume.
IV. Advices and examples
Šimić G et al. (1997) Volume and number of neurons of the human hippocampal formation in normal aging and Alzheimer's disease. J. Comp. Neurol. 379: 482-494.
OPTICAL DISECTOR
Šimić G et al. (2000) Ultrastructural analysis and TUNEL demonstrate motor neuron apoptosis in Werdnig-Hoffmann disease. J. Neuropathol. Exp. Neurol. 59: 398-407.
PHYSICAL DISECTOR
Šimić G et al. (2005) Hemispheric asymmetry, modular variability and age-related changes in the human entorhinal cortex. Neuroscience 130: 911-925.
OPTICAL FRACTIONATOR
Properties of modern stereological methods
Estimates first-order parameters of biological structures (e.g. volume, surface area, length, number) and their variability from a small sample of the population of interest.
Uses highly efficient systematic sampling.
Efficiency based on true variability of objects and features of biological interest.
Advances
Avoids tissue processing artifacts, e.g., shrinkage/expansion, lost caps.
Strong mathematical foundation in stochastic geometry and probability theory, but:
Advanced mathematical background not required for users.
Computorized or not?
Doesn't require computerized hardware-software systems, but:
Computerized stereology systems are very efficient.
Statistical power for studies of the same parameter is cumulative across populations.
Last but not least:
Considered state-of-the-art by journal editors and grant review study groups.
Worldwide cooperation possible, in theory, through Web-accessible databases.
Some of the optionson the market
C.A.S.T. Grid (Olympus / Zeiss)
StereoInvestigator and Neurolucida (MicroBrightField)
Stereologer (Systems Planning and Analysis)
1. Some new, simple and efficient stereological methods and their use in pathological research and diagnosis. Gundersen, H.J.G., T.F. Bendsen, L. Korbo, N. Marcusen, A. Moller, K. Nielsen, J.R. Nyengaard, B. Pacakkenberg, F.B. Sorensen, A. Vesterby, and M.J. West. APMIS 96: 379-394. 1988.
2. The new stereological tools: Disector, fractionator, nucleator and point sampled intercepts and their use in pathological research and diagnosis. Gundersen, H.J.G., P. Bagger, T.F. Bendsen, et. al. APMIS 96: 857-881. 1988.
Two most important references in the field:
Reference Sites
http://www.3dcounting.html/
http://www.stereologer.com/Stereo_Exec.html
http://www.ssrecn.html
http://www.phtshp.htm/
http://www.confocl.htm/
http://www.ippage.htm/
http://www.index.html/
Conclusion
The key to doing science efficiently is to:
Always use valid techniques (strive for techniques that are guaranteed to be unbiased)
Balance the accuracy of the estimate against the cost of performing the experiment
