A Repeated Latin Square (RLS) exper

A Repeated Latin Square (RLS) experimental design
was implemented for this experiment, using a factorial
treatment structure (Lenter and Bishop, 1993). Two
matching Latin squares were created, one for each gender,
with testing of males and females performed independently
within their own squares. This design permitted controlled
investigation of potential gender effects, including genderbased
interactions with experimental treatments. Should
gender interactions be found to exist, each gender could be
analyzed separately. The Latin squares were organized
based upon the use of 12 subjects for each gender, 12
chairs, and six postural treatments. The randomized Latin
squares used in this experiment were generated based on
the process and the random number table detailed in
Lenter and Bishop (1993). This resulted in 144 data points
for each gender (12 subjects
12 chairs), and 288 data
points total.
The six postural treatments were created using a
combination of three different trunk–thigh angles (1001,
1101, 1201) with each angle evaluated both with and
without the use of armrests, thus forming a 2
3 factorial
treatment structure (Lenter and Bishop, 1993). These
specific angles and the use of armrests were of particular
interest due to their use in prior studies which reported
significant findings for other physiological variables
associated with increased (reclined) postural angle (Andersson
and O¨ rtengren, 1974a, b; Andersson et al.,
1974a, b; Chaffin et al., 1999). With regard to seat pan
interface pressure, the interest in potential pressure
differences due to postural angle was based upon offloading
of body weight onto the backrest and armrests. As
the backrest reclines to a greater degree, more of the upper
body weight is borne by the backrest support, reducing
the percentage of body weight transferred downwards to
the seat pan. Seat pan interface pressure occurs due to the downward force of gravity upon the body. This results in
the upper body weight being transferred via the spine to the
pelvic structure. The pelvis in turn bears the resultant
downward force of the upper body, with peak seat pan
interface pressures occurring under the ischial tuberosities
(Andersson et al., 1979; Congleton et al., 1988; Chaffin
et al., 1999; Sember, 1994). Since increased offloading of
upper body weight due to backrest angle and armrest use
could reduce the resultant downward force borne by the
pelvic structure, increased trunk–thigh angle and armrest
usage was expected to demonstrate a reduction in seat pan
interface pressures.
The primary dependent variables measured with regard
to interface pressure distributions included peak and mean
pressure. Peak pressure was defined as the highest point of pressure observed in the interface pressure distribution
during the testing period. This typically occurs under the
location of the ischial tuberosities. The resolution of the
sensor mat used was 1.27 cm2, thus this would be the
highest 1.27 cm2 cell in the 45.7 cm
45.7 cm (2088.5 cm2)
mat. Mean pressure was defined as the averaged pressure
observed across all activated cells in the sensor mat (note
that only cells receiving 5mmHg of pressure or more were
considered ‘‘activated’’).