Ergonomical study regarding working in seating postures of the dentists.
Kulcsar, Raul Miklos ; Argesanu, Veronica ; Rusu, Darian 等
1. INTRODUCTION
The posture is the human body behaviour in relation with the
environment in which he lives, and in relation with the laws that
governs these environment, first of all the force of gravity. To do
this, man has developed a specialized structure to overcome gravity,
called the tonic postural system of vertical stability.
The sitting position is where most of us get into trouble with poor
postural habits. This is especially true when driving or using a
computer. As we focus on the activity in front of us we tend to protrude the head and neck forward. Because the body follows the head, the
thoracic and lumbar spine tends to round forward as well. When this
occurs, the weight of the head and upper body is no longer balanced over
the spinal column but instead must be supported by increased muscular
energy and placing spinal ligaments on stretch. Over time this leads to
fatigue and eventually even pain in the neck and upper back.
Sitting with proper postural alignment will allow one to work more
efficiently with less fatigue and strain on your body's ligaments
and muscles.
Regarding the working environment in the field of the dental
physician, most data available on ergonomics is based on observation and
on personal experience of the physicians themselves. Most of the
work-related physical problems are, in general, only discovered after
the harm has already been done and in most cases the need for resting
the damaged muscles and tending to the affected part leads to the need
of a certain period of less to no activity for the physician. (Hokwerda
et al., 2007).
For this study were chosen 5 different seated working postures of
the dental physician. The last 2 postures are optimal from ergonomic
point of view.
These seated working postures are:
1) Rotate left 70[degrees];
2) Rotate left 70[degrees] and bending 25[degrees];
3) Rotate left 45[degrees] and bending 25[degrees];
4) Without rotation, bending 30[degrees];
5) Without rotation, bending 45[degrees].
2. GENERATING HUMAN BODY MODEL POSTURES AND PRELEVATION OF DATA
The human body model was generated using the AnyBody Modeling
System[TM] software.
[FIGURE 1 OMITTED]
The body models are available in the standard demo package that can
be used in conjunction with the ANYBODY human body simulation software.
Starting from a standing human model, using pre-defined muscles and bone
attachments, and building the seated working postures scenarios, have
been developed.
For the seated position, the chair was added virtually through a
node that offers a stabile platform for the pelvis region. The angles
for the legs were obtained from an ideal theoretical position for the
purpose of minimising their involvement in the general muscle activity
of the body system.
All simulated positions have been designed for similar hands and
shoulders activity. The overall angle differences for the hands in the
eight simulations is minimised so that the general difference in the
total muscle activity is given by the other muscles. This allows for a
clear view of the influence of the different postures on the system.
All activities include certain tensions in the hands given by an
external load. Because of this factor, all models have forces attached
to the nodes belonging to each of the hands. This ensures that the data
output is similar to that which would be obtained from a real life model
and further adds to the accuracy of the model.
All movement patterns were carefully studied for muscle collision
and kinematical correctitude; after all data was considered viable, the
next phase of the study--using inverse dynamics, was conducted. The data
was then extracted from the output of the program for the various muscle
groups that were of interest (shoulders and arms, general muscle
activity). The most relevant data was considered the shoulders and arms
muscle fatigue per cycle investigated. Muscle fatigue (Activity) is
defined by the ANYBODY solver as muscle force divided by strength
(anybodytech.com, 2007).
3. THERMOGRAPHIC EXPERIMENT
The temperature recorder (thermograph) is an important tool for
medical diagnosis because science has managed to prove that all diseases
cause temperature changes in a suffering organ. Some types of disorders
lower the temperature in that particular organ, others raise it.
The infrared camera we used was FLIR B200 which is based on
settings that sense and record on tape the cold and warm areas of the
human body by detecting infrared radiations which react to blood flow.
With the help of the infrared camera we took a set of pictures
which give the possibility to analyze the body temperature distribution
and at the same time the increase of muscle contraction.
The study underwent by keeping a long time, each working posture of
the 5 above mentioned, by the dental physician, starting from a resting
posture.
The conditions that had to be fulfilled to assure the accuracy of
the study were the following:
* Low surrounding temperature, to avoid errors in measuring the
real body temperature (the air was renewed, the air conditioner was
turned on and the lights were turned off);
* The dentist's position was maintained for a longer period of
time;
* The dentist posed shirtless so that the body temperature could be
most accurate.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
4. CONCLUSION
After a careful examination of the data and statistical analysis, a
clear distinction between the energy consumption for the 5 seated
working postures became apparent. According to the results the ergonomic
optimal posture is the 4th one. This result is validated also by the
thermo graphic experiment by highlighting the temperature distribution.
This shows that the posture with the smallest energy consumption and
muscle activity is the 4th one (without rotation, bending 30[degrees]).
Another aspect of the study is the possibility of pointing out the
individual muscle strain for the various shoulder and arm muscles. The
impact of such data can lead to improvement of movement ergonomics and
development of specific work training that can relieve the tension
generated during certain stages of physical activity.
This sort of data obtained from working posture simulations and
compared with thermo graphic results, is very useful in ergonomic design
of the dental equipment, and also in improving the prevention of the
musculoskeletal disorders by using ergonomics.
5. ACKNOWLEDGEMENTS
This work was partially supported by the strategic grant
POSDRU/88/1.5/S/50783, Project ID50783 (2009), co-financed by the
European Social Fund--Investing in People, within the Sectoral
Operational Programme Human Resources Development 2007-2013.
6. REFERENCES
Argesanu V., Kulcsar R.(2010): Current Methods of Investigation of
the Postural Status in Dental Medicine. Milenium III Medicine, The
International Congress of Medical Days in Banat, 15th Edition, Timisoara
Medical Journal, Vol. 60, 1/2010, ISSN 1583-5251, Timisoara.
Dragulescu, D. (2005). Modelling in Biomechanics, Editura Didactica
si Pedagogica, ISBN 973-30-1725-6, Bucuresti
Hokwerda, O (2008). Ergonomic objections against a unit-cart on the
right or left side of the patient chair, Available from:
www.esde.org/docs/ergonomic_objectioins_against_a_unit_or_cart
_next_to_patient_cha.pdf Accessed: 2009-01-25
Hokwerda, O.; Wouters J. & de Ruijter, R. (2007). Ergonomic
requirements for dental equipment, Available from:
www.optergo.com/images/Ergonomic_req_april2007.pdf Accessed: 2009-01-15
Hokwerda, O.; de Ruijter, R. & Zijlstra-Shaw, S. (2005).
Adopting healthy sitting posture during patient treatment, Available
from: www.optergo.com/uk/images/Adopting.pdf Accessed: 2009-01-14
*** (2007) www.anybodytech.com/index.php?id=691 ANYBODY technology
tutorials, inverse dynamics analysis, Accesed on: 2009-03-20.
*** www.flirb200.com/ FLIR B200 Infrared Camera Users's Manual
and Tutorials, Accesed: 2010-06-03.
