This vignette is designed to give you a good introduction to some of the key features of nat by teaching you about how it handles individual neurons and collections of neurons.
The source code for this vignette is available at https://github.com/natverse/nat/blob/master/vignettes/neurons-intro.Rmd. If you find something unclear or notice a typo, I would be very happy if you would click on the Pencil Icon on that page or follow this link to edit and suggest an alternative wording. Don’t be shy about doing this; I have to review any change and even if your suggestion is not perfect it will still be a prompt for me to improve this document. Thank you!
Install the package if required
install.packages('nat', dependencies = TRUE)
Load the package
library(nat)
There are a number of basic built in types of data in R such as vectors and matrices, but it is also very easy to define new data types with specialised features to enable powerful and efficient analysis of particular kinds of data. These specialised data types are called classes and a specific instance of a class is an object (a neuroscience analogy: this is the difference between talking about the general class of mitral cells and the specific cell that you just sealed onto with your patch clamp electrode.)
We will look at two key classes that nat defines for handling 3D structures of neurons
neuron
neuronlist
As an example we’re going to look at a data set of olfactory projection neurons originally published as Supplemental Information to accompany Jefferis, Potter et al, Cell (2007). A subset of the original data are distributed as a sample data object with the nat package, which we can load like so.
data("Cell07PNs")
For more information about these data see Cell07PNs.
This Cell07PNs
object has two classes
neuronlist
and the base class list
class(Cell07PNs)
## [1] "neuronlist" "list"
Many R objects inherit from the base class list
(objects
can have multiple classes in the same way that a mitral cell is also
neuron) because this is a convenient container class into which you can
put a variety of different kinds of data. In this case the
Cell07PNs
neuronlist
contains 40 objects:
length(Cell07PNs)
## [1] 40
# access the first neuron in the neuronlist
class(Cell07PNs[[1]])
## [1] "neuron" "list"
each representing a traced neuron. We will now look in detail at these two classes.
We start by extracting the first neuron in Cell07PNs, and assigning it to a variable. We can then plot the neuron so that we have an image of what we are talking about.
=Cell07PNs[[1]]
n1plot(n1)
The str
function (short for structure) allows us to take
a look at the internal structure of this neuron object.
# Use =1 so that we don't show complete structure
# for objects inside n1
str(n1, max.level=1)
## List of 24
## $ CellType : chr "DA1"
## $ NeuronName : chr "EBH11R"
## $ InputFileName: 'AsIs' chr "/GD/projects/PN2/TransformedTraces/DA1/EBH11R.tasc"
## $ CreatedAt : POSIXt[1:1], format: "2006-01-17 15:21:14"
## $ NodeName : Named chr "jefferis.joh.cam.ac.uk"
## ..- attr(*, "names")= chr "nodename"
## $ InputFileStat:'data.frame': 1 obs. of 10 variables:
## $ InputFileMD5 : Named chr "fcacee3f874cbe2c6ad96214e6fee337"
## ..- attr(*, "names")= 'AsIs' chr "/GD/projects/PN2/TransformedTraces/DA1/EBH11R.tasc"
## $ NumPoints : int 180
## $ StartPoint : num 1
## $ BranchPoints : num [1:16] 34 48 51 75 78 95 98 99 108 109 ...
## $ EndPoints : num [1:18] 1 42 59 62 80 85 96 100 102 112 ...
## $ NumSegs : int 33
## $ SegList :List of 33
## $ d :'data.frame': 180 obs. of 7 variables:
## $ OrientInfo :List of 5
## $ SegOrders : num [1:33] 1 2 2 3 4 4 3 4 5 5 ...
## $ MBPoints : int [1:2] 34 48
## $ LHBranchPoint: int 75
## $ SegTypes : num [1:33] 1 3 1 3 3 3 1 2 2 2 ...
## $ AxonSegNos :List of 3
## $ LHSegNos : num [1:26] 8 9 10 11 12 13 14 15 16 17 ...
## $ MBSegNos :List of 2
## $ NumMBBranches: num 2
## $ AxonLHEP : num 72
## - attr(*, "class")= chr [1:2] "neuron" "list"
From this you can see that there are a large number of fields inside
the neuron. Each field can be accessed using the $
or
[[
operators
$NumPoints n1
## [1] 180
"NumPoints"]] n1[[
## [1] 180
There are a set of core fields (described in ?neuron
documentation); the key ones will be described shortly. However there
are also quite a few user fields in this neuron and you can safely add
any field you like so long as its name does not clash with an existing
field. For example:
$Comment='The sex of this specimen is uncertain' n1
The single most important field in a neuron is the $d
data.frame
. This contains a block of data closely
reminiscent of the SWC data format for traced neurons:
str(n1$d)
## 'data.frame': 180 obs. of 7 variables:
## $ PointNo: int 1 2 3 4 5 6 7 8 9 10 ...
## $ Label : num 2 2 2 2 2 2 2 2 2 2 ...
## $ X : num 187 187 188 188 188 ...
## $ Y : num 133 131 130 129 129 ...
## $ Z : num 88.2 90.6 93.1 95 97.5 ...
## $ W : num 1.01 1.27 1.14 1.27 1.27 1.27 1.27 1.27 1.27 1.27 ...
## $ Parent : num -1 1 2 3 4 5 6 7 8 9 ...
Each row defines a node in a branched tree with a unique integer
identifier, PointNo
, normally but not always sequentially
numbered from 1. The X,Y,Z
columns encode the position of
each vertex and the W
column encodes the diameter of the
neurite at that position.
R’s simple S3
object oriented system allows specialised functions for particular
classes to be defined. These functions tailored to a particular class
are called methods. Methods can be provided for pre-existing
functions supplied with base R as well as new user-written functions.
The system is quite simple. If a function foo
is defined as
a generic function then you can define new functions called
foo.bar
that will be called when you write
foo(x)
and x
has class `bar.
We already used one such method without comment,
plot.neuron
. There is a base R function called
plot
. nat defines a new function called
plot.neuron
, which R interprets as a plot
method specialised for neuron
objects. When the base R
plot
function is called, it looks at the class of its first
object to see whether a specialised method exists. If there is none, it
will use a fallback method called plot.default
.
The plot.neuron
method interprets the branching
structure of a neuron and draws line segments joining up the connected
nodes at the appropriate 2D positions. You can compare it with what you
would get if you just plotted the XY position of all nodes joined
together by a single line:
plot(n1$d$X, n1$d$Y, type = 'l')
You can find out what methods are available for a particular class like so:
methods(class = 'neuron')
## [1] * + - /
## [5] all.equal as.neuron as.ngraph as.seglist
## [9] boundingbox branchpoints dotprops endpoints
## [13] ndigest nvertices plot plot3d
## [17] potential_synapses prune resample rootpoints
## [21] scale subset summary write.vtk
## [25] xform xyzmatrix xyzmatrix<-
## see '?methods' for accessing help and source code
You can then find the help page for any method in the console with
?plot.neuron
. Note that if you write ?plot
you
will get the documentation for the basic plot
function
supplied with R.
It is also good idea to look at nat’s function reference page which groups available functions into categories that often reflect the class of object they can work on.
In R, operators such as *
or +
are actually
special functions with two arguments, so one can add methods for these
in the same way. In the following example we use this arithmetic to
shift a neuron by a small amount:
plot(n1, col = 'black', WithNodes = F, main="Shifting neurons")
# shift by 3 microns in x,y,z
plot(n1+3, col = 'red', add = TRUE, WithNodes = F)
# shift by -5 microns in y
plot(n1+c(0,-5,0), col = 'blue', add = TRUE, WithNodes = F)
Another specialised method is subset.neuron
which we can
use to extract part of a neuron into a new object. For example, a simple
spatial criterion, X location must be >240, is used to extract the
axon terminal arborisation field in this example
plot(n1, col = 'black', WithAllPoints = T, main="Subsetting a neuron")
# keep only nodes with X position >20
=subset(n1, X>240) n1.lh
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
# plot the selected part of the neuron in blue
plot(n1.lh, col='blue', lwd=3, add=TRUE)
# add a line illustrating the cut point
abline(v=240, lty=2)
We can also summarise the morphological properties of a neuron using
the summary.neuron
method, which allows us to compare
measurements for the original neuron and the axon arbour that we just
cut out above.
summary(n1)
## root nodes segments branchpoints endpoints cable.length
## 1 1 180 33 16 18 297.1763
summary(n1.lh)
## root nodes segments branchpoints endpoints cable.length
## 1 1 111 27 13 15 156.7654
See nat’s function reference page for additional functions for working with neurons.
The data
statement above loaded a
neuronlist
object called Cell07PNs
containing
40 neuron
objects. neuronlist
objects are key
data structures in nat for convenient handling of collections of
neurons.
The diagram above presents the structure of a neuronlist,
x
, which contains 5 neurons. The main structure is an R
list
object, which in this case contains 5 slots. Each slot
contains a neuron with a unique name. In addition to this list of
neurons there is an optional attached data.frame
(another
standard R class). When present, each neuron in the main list must have
a matching row in this data.frame
.
Neuronlists can be manipulated use the square bracket subscript operator to extract or replace a subset of their elements. Crucially when this happens the corresponding rows of the attached metadata are also selected as diagrammed for the result of x[1:3] (right hand side of figure above).
When subscripting any list in R, it is very important to understand the difference between using the single and double bracket operator. We can illustrate this difference as follows:
The single bracket operator makes a new list containing a specified
subset of elements in the original list, while the double bracket
operator extracts the object at the given position. So in the figure
x[1]
is a neuronlist
object of length 1,
whereas x[[1]]
is the neuron
object at the
first position in the list.
Let us start by extracting the first five neurons from our sample data.
# we can select neurons by indexing
=Cell07PNs[1:5]
first5summary(first5)
## root nodes segments branchpoints endpoints cable.length
## EBH11R 1 180 33 16 18 297.1763
## EBH20L 1 200 26 12 15 327.0929
## EBH20R 1 199 25 12 14 347.6153
## EBI12L 1 169 23 11 13 294.4680
## EBI22R 1 160 27 13 15 303.0150
Each neuron in the neuronlist has an associated name which can be
used to select it. We can get the names of all neurons using the
names
function.
names(Cell07PNs)
## [1] "EBH11R" "EBH20L" "EBH20R" "EBI12L" "EBI22R" "EBJ23L" "EBJ3R" "EBN19L"
## [9] "EBO15L" "EBO53L" "ECA34L" "ECB3L" "LI23L" "LIC2R" "LJ5L" "MC3B"
## [17] "MH16L" "MM14L" "NA7L" "NH15L" "NH29B" "NI16L" "NIA8L" "NIA8R"
## [25] "NNA9L" "NNC4R" "NNE1L" "OFD2L" "OKC9R" "SDD8L" "SH21L" "SL20L"
## [33] "TKC8R" "TL4R" "TS7L" "TT27R" "VA15R" "VA20R" "VB37L" "VB58L"
=Cell07PNs[c("EBH11R", "EBH20L", "EBH20R")]
nl3all.equal(nl3, Cell07PNs[1:3])
## [1] TRUE
You can also use the $
operator to access a single
neuron e.g. Cell07PNs$EBH11R
. This can be quite useful when
working interactively in the console because RStudio will offer to
autocomplete the neuron name when you start typing past the
$
symbol, but is not recommended for scripts.
The names of neurons are also used to index a data.frame
object attached to the neuronlist with one row for each neuron. You can
use the head
function to give a summary of the attached
metadata in this neuronlist. Using the as.data.frame
method
on a neuronlist allows you to extract this attached metadata to a
separate object.
head(Cell07PNs)
## Brain RegistrationScore Notes Glomerulus Batch Directory Traced
## EBH11R EBH11R 4 DA1 PN2 unsure yes
## EBH20L EBH20L 4 DL3 PN2 unsure2 yes
## EBH20R EBH20R 4 DA1 PN2 unsure2 yes
## EBI12L EBI12L 4 DA1 PN2 unsure3 yes
## EBI22R EBI22R 4 DL3 PN2 unsure3 yes
## EBJ23L EBJ23L 4 DL3 PN2 unsure4 yes
## Scored.By Sex Include ID HaveWarp HaveAsc
## EBH11R ACH M EBH11R TRUE TRUE
## EBH20L ACH EBH20L TRUE TRUE
## EBH20R ACH M EBH20R TRUE TRUE
## EBI12L ACH F EBI12L TRUE TRUE
## EBI22R ACH EBI22R TRUE TRUE
## EBJ23L ACH EBJ23L TRUE TRUE
## TraceFile AscBatch Status
## EBH11R /GD/projects/PN2/TransformedTraces/DA1/EBH11R.tasc New
## EBH20L /GD/projects/PN2/TransformedTraces/DL3/EBH20L.tasc New
## EBH20R /GD/projects/PN2/TransformedTraces/DA1/EBH20R.tasc New
## EBI12L /GD/projects/PN2/TransformedTraces/DA1/EBI12L.tasc New
## EBI22R /GD/projects/PN2/TransformedTraces/DL3/EBI22R.tasc New
## EBJ23L /GD/projects/PN2/TransformedTraces/DL3/EBJ23L.tasc New
## GlomSeq NumNAs MBP1 MBP2 LHBP PNType Seq nTrees StartPoint
## EBH11R 1 0 34 48 75 iPN 13 1 1
## EBH20L 1 0 29 29 77 iPN 15 1 1
## EBH20R 2 0 24 80 147 iPN 16 1 1
## EBI12L 3 0 29 59 89 iPN 18 1 1
## EBI22R 2 0 34 34 56 iPN 20 1 1
## EBJ23L 3 0 23 23 52 iPN 21 1 1
## CreatedAt
## EBH11R 2006-01-17 15:21:14
## EBH20L 2006-01-17 15:21:14
## EBH20R 2006-01-17 15:21:14
## EBI12L 2006-01-17 15:21:15
## EBI22R 2006-01-17 15:21:15
## EBJ23L 2006-01-17 15:21:15
## WarpFile
## EBH11R /GD/projects/PN2/allreg/warp/unsure/average-goodbrains_EBH11R101_warp_m0g40c4e1e-1x16r3.list
## EBH20L /GD/projects/PN2/allreg/warp/unsure2/average-goodbrains_EBH20L101_warp_m0g40c4e1e-1x16r3.list
## EBH20R /GD/projects/PN2/allreg/warp/unsure2/average-goodbrains_EBH20R101_warp_m0g40c4e1e-1x16r3.list
## EBI12L /GD/projects/PN2/allreg/warp/unsure3/average-goodbrains_EBI12L101_warp_m0g40c4e1e-1x16r3.list
## EBI22R /GD/projects/PN2/allreg/warp/unsure3/average-goodbrains_EBI22R101_warp_m0g40c4e1e-1x16r3.list
## EBJ23L /GD/projects/PN2/allreg/warp/unsure4/average-goodbrains_EBJ23L101_warp_m0g40c4e1e-1x16r3.list
=as.data.frame(Cell07PNs)
dfnrow(df)
## [1] 40
# rownames of data.frame are the same as names of Cell07PNs list.
all.equal(rownames(df), names(Cell07PNs))
## [1] TRUE
You can use columns in the attached metadata in expressions that select or operate on the neurons in the list. In the next two examples we
subset
the neurons in a neuronlist based on a metadata
columnwith
function to carry out a calculation using
column(s) of metadata.# subset.neuronlist method (which you call using the subset function)
=subset(Cell07PNs, Glomerulus=="DA1")
da1n
# with.neuronlist method
with(Cell07PNs, table(Glomerulus))
## Glomerulus
## DA1 DL3 DP1m VA1d
## 11 10 8 11
There is a second approach to accessing this attached metadata
data.frame, using the square bracket operator with two arguments as used
for subscripting (2D) matrices or data.frames
. For example
we can access the Glomerulus
column like so:
'Glomerulus'] Cell07PNs[,
## [1] DA1 DL3 DA1 DA1 DL3 DL3 VA1d VA1d VA1d VA1d DP1m DP1m DA1 DL3 VA1d
## [16] VA1d DL3 DA1 DA1 VA1d VA1d VA1d DL3 VA1d DP1m DP1m DP1m DP1m DP1m DP1m
## [31] DA1 DL3 DL3 DL3 VA1d DA1 DA1 DA1 DL3 DA1
## Levels: DA1 DL3 DP1m VA1d
This approach has some features that make for additional flexibility. For example you can acess the whole data.frame like so:
summary(Cell07PNs[,])
The form [,]
which includes a comma implies two
(missing) arguments. nat therefore interprets this as
request for the 2D data.frame attached to Cell07PNs rather than the
neuronlist itself. You can also use this notation to add new columns or
modify existing columns in place.
'NewColumn'] = somevariable
Cell07PNs[, "Sex"] = sub("F", "female", Cell07PNs[, "Sex"])
Cell07PNs[, "Sex"] = sub("M", "male", Cell07PNs[, "Sex"]) Cell07PNs[,
You can also access selected rows of the data.frame in the normal way:
1:5, "Glomerulus"]
Cell07PNs["Sex"]=="F", "Glomerulus"] Cell07PNs[Cell07PNs[,
There are quite a few methods defined for the neuronlist
class:
methods(class = "neuronlist")
## [1] * + - /
## [5] [ [<- as.data.frame as.neuronlistfh
## [9] c data.frame<- dimnames dotprops
## [13] droplevels head intersect mirror
## [17] nvertices plot plot3d potential_synapses
## [21] prune setdiff subset summary
## [25] tail union with xform
## [29] xyzmatrix xyzmatrix<-
## see '?methods' for accessing help and source code
For example we can scale the position (and diameter) of all of the
neurons in a neuronlist using the *
operator:
# convert from microns to nm
= Cell07PNs*1e3
Cell07PNs.nm plot(Cell07PNs.nm)
There is also a more powerful xform
function that allows
arbitrary transformations to be applied. For example here we apply a 3D
rotation expressed as a homogeneous affine matrix:
# define a 180 degree rotation around the x axis
=cmtkparams2affmat(rx=180)
rotm# remove tiny values due to rounding errors
=zapsmall(rotm)
rotmplot(xform(Cell07PNs, rotm))
More generally any function that works on a neuron can be applied to
a neuronlist by using the function nlapply
. This is an
analogue to base R’s lapply
function. This will take care
of returning a new neuronlist with the attached metadata and includes
additional features such as error tolerance, progress bars and
parallelisation for multi-core machines. It is worth reviewing the help
and examples for this function carefully if you start to work regularly
with neuronlists.
We have already seen that we can plot a single neuron (the first) like so:
plot(Cell07PNs[[1]])
The purple node higlights the root or soma of the neuron, red nodes
are branch points, green nodes are end points. We can also label each
node with its PointNo
index.
plot(Cell07PNs[[1]], col='red', WithText=T)
Multiple neurons can be plotted by passing a whole neuronlist or indexing it
plot(Cell07PNs[1:3])
More complex subsets are possible by using
plot.neuronlist
subset argument (which works in the same
way as the subset.neuronlist
function). For example here we
select neurons by which olfactory glomeruli their dendrites occupy:
plot(Cell07PNs, subset=Glomerulus!="DA1", col='grey', WithNodes=F, main="DA1 neurons")
plot(Cell07PNs, subset=Glomerulus=="DA1", add=TRUE)
So far we have only used 2D plots in this document, but especially for interactive analysis and exploration, it is much more helpful to have 3D plots that can be rotated, zoomed etc. nat provides numerous functions for 3D plots based on the rgl package. It is actually possible to embed fully interactive 3d figures in rmarkdown reports like this one by setting the webgl chunk option.
clear3d()
plot3d(Cell07PNs[[1]], col='red')
# set a grey background so it's easier to see extent of the webgl canvas
bg3d(col='lightgrey')
You should be able to rotate (click and drag) and zoom (mouse wheel) this figure.
Since this results in quite large html files when used with many neurons, we will not use it further here. For now let’s show a plot in which we both select a subset of neurons and colour them according to their glomerulus of origin.
# 3d plot of neurons from olfactory glomeruli beginning with a D
# coloured by glomerulus
=plot3d(Cell07PNs, subset=grepl("^D", Glomerulus), col=Glomerulus,
rvallwd=2, WithNodes=FALSE)
# make a legend so that you know which colours match which glomerulus
plot.new()
with(attr(rval,'df'), legend('center', legend = unique(Glomerulus), fill=unique(col)))
To close this tutorial, let’s do some morphological analysis of the
neurons in this dataset. There are second order olfactory projection
neurons originating from 4 different glomeruli in the
Cell07PNs
sample dataset, each coming from a different
animal. We can ask whether their axon terminal arborisations in a brain
area called the lateral horn show any features that are distinctive for
different classes. This would be consistent with the hypothesis that
information from different glomeruli (i.e. olfactory channels) is
handled in a stereotyped way in this brain area.
Let’s start by cutting out the arbour within the lateral horn from all of the neurons. We’ll use a very simple approach of cutting at X=250, although nat has more sophisticated ways to do this e.g. by using 3D spaces defined by a surface mesh.
# note that we had to use OmitFailures=T due to a problem with the graph
# structure of one neuron
=nlapply(Cell07PNs, subset, X>250, OmitFailures = T) lha
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
## Warning in graph.dfs(x, root = origin, father = TRUE, neimode = "all"): Argument
## `neimode' is deprecated; use `mode' instead
# Let's plot what we have colouring by glomerulus
plot(lha, col=Glomerulus, WithNodes=F)
Now we can get a basic statistical summary by axon arbour.
=summary(lha, include.attached.dataframe = TRUE)
lhstatsboxplot(lhstats$cable.length~lhstats$Glomerulus, log='y')
boxplot(lhstats$branchpoints~lhstats$Glomerulus)
We can also calculate the median position of the arbour for each neuron and add that to the lhstats database
# quick function to calculate centroid
<- function(n) {
arbour_centroid # extract location of all points in neuron object
=xyzmatrix(n)
xyzs# median in all 3 axes (=>2 columns)
apply(xyzs, 2, median)
}# note that we have to transpose because sapply results in x,y,z rows
=t(sapply(lha, arbour_centroid))
centroids=cbind(lhstats, centroids) lhstats
Finally we can take these data and see how well we can predict the
identity of the neuron (i.e. its glomerulus) based on the statistics of
the axon arbour in the lateral horn. We use the linear discriminant
analysis (provided by the function lda
in recommended
package MASS
). This also runs a leave one out
cross-validation to get a more robust initial estimate of prediction
error.
library(MASS)
= lda(Glomerulus ~ cable.length+X+Y+Z+branchpoints, lhstats, CV = T)
lda.fit table(lda.fit$class, lhstats$Glomerulus)
##
## DA1 DL3 DP1m VA1d
## DA1 10 2 0 1
## DL3 0 7 0 0
## DP1m 0 0 8 0
## VA1d 1 0 0 10
The prediction accuracy of 35/39 i.e. just under 90% is already very good compared with a chance level of about 25% for these 4 classes.
We hope this tutorial will provide you with a good foundation for further use of the nat and related packages. Please visit the main nat README for suggestions of resources to learn more and solve problems. You may also find that some time spent reading Hadley Wickham’s Advanced R is a worthwhile investment. I recommend the first 7 chapters (Introduction to OO field guide) as material that will be helpful for anyone who intends to carry out a significant project using R.