osteo | R Documentation |
These data give the three-dimensional locations of osteocyte lacunae observed in rectangular volumes of solid bone using a confocal microscope.
There were four samples of bone, and ten regions were mapped in each bone, yielding 40 spatial point patterns. The data can be regarded as replicated observations of a three-dimensional point process, nested within bone samples.
data(osteo)
A hyperframe
with the following columns:
id | character string identifier of bone sample |
shortid | last numeral in id |
brick | serial number (1 to 10) of sampling volume within this bone sample |
pts | three dimensional point pattern (class pp3 ) |
depth | the depth of the brick in microns |
These data are three-dimensional point patterns representing the positions of osteocyte lacunae, holes in bone which were occupied by osteocytes (bone-building cells) during life.
Observations were made on four different skulls of Macaque monkeys iusing a three-dimensional microscope. From each skull, observations were collected in 10 separate sampling volumes. In all, there are 40 three-dimensional point patterns in the dataset.
The data were collected in 1984 by A. Baddeley, A. Boyde, C.V. Howard and S. Reid (see references) using the tandem-scanning reflected light microscope (TSRLM) at University College London. This was one of the first optical confocal microscopes available.
Each point pattern dataset gives the (x,y,z)
coordinates
(in microns) of all points visible in a
three-dimensional rectangular box (“brick”) of dimensions
81 \times 100 \times d
microns,
where d
varies.
The z
coordinate is depth into the bone
(depth of the focal plane of the confocal microscope); the (x,y)
plane is parallel to the exterior surface of the bone;
the relative orientation of the x
and y
axes is not important.
The bone samples were three intact skulls and one skull cap, all originally identified as belonging to the macaque monkey Macaca fascicularis, from the collection of the Department of Anatomy, University of London. Later analysis (Baddeley et al, 1993) suggested that the skull cap, given here as the first animal, was a different subspecies, and this was confirmed by anatomical inspection.
The following extract from Baddeley et al (1987) describes the sampling procedure.
The parietal bones of three fully articulated adult Macaque monkey
(Macaca fascicularis) skulls from the collection of
University College London were used. The right parietal bone was
examined, in each case, approximately 1 cm lateral to the sagittal
suture and 2 cm posterior to the coronal suture. The skulls were
mounted on plasticine on a moving stage placed beneath the TSRLM.
Immersion oil was applied and a \times 60
, NA 1.0 oil immersion
objective lens (Lomo) was focussed at 10 microns below the cranial
surface. The TV image was produced by a Panasonic WB 1850/B camera
on a Sony PVM 90CE TV monitor.
A graduated rectangular counting frame
90 \times 110
mm (representing
82 \times 100
microns in real units)
was marked on a Perspex overlay
and fixed to the screen. The area of tissue seen within the frame defined
a subfield: a guard area of 10 mm width was visible on all sides of the
frame. Ten subfields were examined, arranged approximately in
a rectangular grid pattern, with at least one field width separating
each pair of fields. The initial field position was determined randomly
by applying a randomly-generated coordinate shift to the moving stage.
Subsequent fields were attained
using the coarse controls of the microscope stage, in accordance with
the rectangular grid pattern.
For each subfield, the focal plane was racked down from its initial
10 micron depth until all visible osteocyte lacunae had been examined.
This depth d
was recorded. The 3-dimensional sampling volume was
therefore a rectangular box of dimensions
82 \times 100 \times d
microns,
called a “brick”.
For each visible lacuna, the fine focus racking control was adjusted until
maximum brightness was obtained. The depth of the focal plane was then
recorded as the $z$ coordinate of the “centre point” of the
lacuna. Without moving the focal plane, the x
and y
coordinates of
the centre of the lacunar image were read off the graduated counting frame.
This required a subjective judgement of the position of the centre of the
2-dimensional image. Profiles were approximately elliptical and the centre
was considered to be well-defined. Accuracy of
the recording procedure was tested by independent repetition (by the
same operator and by different operators) and found to be reproducible
to plus or minus 2 mm on the screen.
A lacuna was counted only if its (x, y)
coordinates lay inside
the 90 \times 110
mm counting frame.
Data were collected by \adrian.
Baddeley, A.J., Howard, C.V, Boyde, A. and Reid, S.A. (1987) Three dimensional analysis of the spatial distribution of particles using the tandem-scanning reflected light microscope. Acta Stereologica 6 (supplement II) 87–100.
Baddeley, A.J., Moyeed, R.A., Howard, C.V. and Boyde, A. (1993) Analysis of a three-dimensional point pattern with replication. Applied Statistics 42 (1993) 641–668.
Howard, C.V. and Reid, S. and Baddeley, A.J. and Boyde, A. (1985) Unbiased estimation of particle density in the tandem-scanning reflected light microscope. Journal of Microscopy 138 203–212.
data(osteo)
if(require(spatstat.geom)) {
osteo
if(interactive()) {
plot(osteo$pts[[1]], main="animal 1, brick 1")
ape1 <- osteo[osteo$shortid==4, ]
plot(ape1, tick.marks=FALSE)
with(osteo, intensity(pts))
plot(with(ape1, K3est(pts)))
}
}
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