Biomechanics of lumbar back pain in dentistry.
Kulcsar, Raul Miklos ; Talpos-Niculescu, Cristina ; Argesanu, Veronica 等
1. INTRODUCTION
Dentists have a high incidence of occupational back pain and
injury, in some cases making it impossible for them to continue to work
as dentists.
The nature of dental work means flexion of the lumbar spine and
subsequent loading on inter vertebral discs or extra tension in the
spinous ligaments both of which can contribute to discomfort and pain.
Mechanisms of trauma are dealt with only briefly because they are
not of widespread interest, and there is little scientific work to
support the classifications of injuries that are currently accepted. On
the other hand, a great deal of effort has been spent on trying to
understand the origins of limited structural failure in spinal tissues,
because such failure is extremely common, is linked to back pain and
tissue degeneration, and may be both preventable and treatable.
Not every case of back pain means that is damage in the tissues,
and many have no detectable spinal pathology of any kind. Evidence is
mounting that mechanical back pain can arise directly from high, but
non-damaging, stress concentrations within innervated tissues.
A review of the literature documenting back/neck pain in dentistry
has found that there are multiple areas of investigation. These include;
firstly, the risk of dentists developing neck/back pain in the first
place, secondly, the prevalence of back pain among the dental profession
(including dental students), thirdly, the various treatments for back
pain prescribed by physicians and, lastly, the various alternative
therapies that can be provided by those working in such areas e.g.
acupuncture.
A number of studies have examined the ergonomics issues associated
with dentists and surgeons. Most of this work has focused on the
symptoms experienced by dentists, perhaps because of their repetitive
daily activity patterns when treating patients.
Back pain is one particularly crucial problem that is in a
dentist's best interest to avoid. A good seating position and
correct posture is vital for the efficient practice of dentistry and to
avoid chronic back pain. In order to do this, it is important to begin
learning the correct posture to use while treating patients early in the
dental career. A recent study has however concluded that body pain is
prevalent even among dental students. Reports of body pain in a dental
student population Rising, David W. DMD et al JADA Vol 136, Jan 2005,
81-86.
It has been found that the constant replication of certain
movements, such as the many movements that a dentist will perform whilst
treating patients in general practice, can contribute to chronic body
pain. Rising and David describe how dentists experience more back pain
than the practitioners in other occupational groups.' (Rising,
David W. et al. 2006).
The authors conducting this study also aimed to estimate the
prevalence and locate the site of body pain that was experienced by the
selected dental students. The results showed that 'chronic
musculoskeletal pain can appear early in a dental career, with more than
70 percent of dental students of both sexes reporting pain by their
third year.' The study also showed that 'men reported having
worst pain in their mid- to lower back.'
The treatment of back pain varies greatly and is often specific to
the individual's symptoms. The conventional methods include:
painkillers, back manipulation and remaining at work. These are the
recommendations from 'Clinical Guidelines for the Management of
Acute Low Back Pain, Royal College of Surgeons 1999'.
Another study, which showed an increased confidence in alternative
therapies for the treatment of back pain, indicates 'most
respondents indicated they would be "very likely" to try
acupuncture, massage or chiropractics for their back pain if they did
not have to pay extra money for it and their physician thought it was a
reasonable treatment option', illustrating that some people may not
be able to afford unproven alternative therapies (Sherman et al. 2004).
The aim of the current study is to determine the load and defective
positions dentists adopt, that triggers the pain and the degeneration of
the tissues in the lumbar spine.
2. MATHEMATICAL MODEL
Mathematical models of the spine depend on material properties
obtained from cadaver experiments, and so incorporate the same
post-mortem artifacts. In addition, they are obliged to make simplifying
assumptions regarding the mechanical behavior complex fiber-reinforced
composite materials such as the anulusfibrosus. Analytical models must
simplify spine anatomy, often to an unrealistic degree. This can be
overlooked if the purpose of the model is merely to demonstrate some
mechanism in a qualitative manner (e.g. to show that any reduction in
nucleus volume will lead to increased radial bulging of inter vertebral
discs) but simplification becomes a problem if the model is used for
quantitative predictions (for example, the angle at which the
anulusfibres become damaged in torsion). Finite element models are able
to represent the anatomy correctly, but for some reason, many of them
concentrate on upper lumbar levels so their conclusions may not be
applicable to the wedge-shaped L4-L5 and L5-S1 discs which are of most
clinical interest. The precise shapes and spacing of the opposing
zygapophysial joint surfaces have a critical effect on the predicted
contact stresses, and even finite element models must approximate these
shapes and spacing from limited cadaveric material. Evidently, the
mathematical modeler can choose between a wide variety of assumptions,
material properties and shapes, until the output of the model appears
'reasonable', so the models have little true predictive power.
However, they are able to explore internal mechanism that would be
difficult to verify experimentally, and they can examine how inter
vertebral discs functions depends on variable factors such as height and
water content. Another problem with most finite element models is that
they are constructed using averaged geometrical and material properties,
so they are unable to predict the diversity of mechanical behavior
encountered in different spines, and which may be of clinical interest.
Some modelers have taken diversity in geometrical and material
properties into account in order to reduce this problem.
3. MEASURING STRESS DISTRIBUTION INSIDE INTERVERTEBRAL DISCS
'Stress profilometry' has revealed the internal
mechanical functioning of the discs to an unprecedented extent, both in
vitro and in vivo. Because of its importance, it is appropriate to
consider briefly how it is performed, and what is actually being
measured.
A static compressive load, sufficient to simulate light manual
labor, is applied to a motion segment for a period of 20s, and during
this time, the distribution of compressive stress within the discs is
measured at a frequency of 25HZ by pulling a miniature pressure
transducer through it, along its sagittal mid-line. The transducer is a
small 2mm long strained gauged membrane mounted in the side of a 1.3mm
diameter needle. The annulus has excellent self-healing properties and
no disc material is expressed through the needle-hole during the
experiments. Rotating the needle about its long axis enables the
vertical and horizontal components of compressive stress to be measured
in successive tests, using the same needle track.
Validation tests have shown that the output of the transducer in
most regions of the disc is approximately equal to the average
compressive stress acting perpendicular to its membrane. This implies
that there is negligible resistance to the matrix deforming into the
slight recess in the needle to press on the transducer membrane. The
outer 2-4mm of annulus is a fibrous solid in which there is unlikely to
be sufficient 'coupling' between matrix and transducer
membrane for reliable recordings to be made. Note that there may be high
tensile forces in the collagen fibers in this region of the disc, but
the transducer does not detect these. The transducer output represents
an average stress acting on the 2mm long membrane, and this may help to
explain why measured compressive 'stress' usually falls
steadily to zero near the disc periphery.
[FIGURE 1 OMITTED]
4. CONCLUSION
Changes in operating methods in dentistry, which have occurred
since the late 1950s, have altered the occupation from a standing to a
sitting profession. Shugars found that good posture correlated
negatively with back pain and, generally, dentists who sat 80% to 100%
of day reported more frequent lower-back pain. Static work in the
sitting posture requiring spinal flexion and rotation has been
associated with increased risk of low back pain (Shugars et al. 1984).
According to Visser and Straker since the introduction of the
sitting posture, lower-extremity problems of the worker have decreased,
but musculoskeletal injuries of upper extremities and the low back have
not been eliminated (Visser & Straker. 1994).
Loads on soft-tissue structures of the lumbar spine and discs are
increased by sitting. Standing can serve as micro break and helps to
prevent and alleviate low-back pain.
Suiting should occur in a chair with lumbar support, not on a
stool. The lumbar support has to be comfortable; it should fit to lumbar
curvature, and contact should be maintained with it while the health
care provider is sitting.
Compromise of the straight spine position results from leaning
forward to improve visibility or because the patient is located too far
away.
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
Visser Jl, Straker LM. (1994). An investigation of disconfort
experienced by dental therapists and assistants at work. Australian
Dental Journal; 39(1): 39-44.
Shugars DA et al.(1984). Musculoskeletal back pain among dentists.
General Dentistry; 32:481-485.
Sherman, Karen J. et al. (2004). Complimentary and alternative
medical therapies for chronic low back pain "What treatments are
patients willing to try?" BMC Complement Altern Med, 4:9
Rising, David W. et al. (2006) Reports of body pain in a dental
student population, DMD et al JADA Vol 136, Jan 2005, 81-86.
Adams, Michel; Burton, Kim; Dolan, Patricia; Nikolai Bogduk. The
Biomechanics of Back Pain, Churchill Livingstone,
Busscher, Iris; Ploegmakers, Joris J. W.; Verkerke, Gijsbertus J.;
Veldhuizen, Albert G. Comparative Anatomical Dimensions Of The Complete
Human And Porcine Spine, European Spine Journal, Volume 19, Number 7 /
July, 2010.
*** The Bambach Saddle Seat
http://www.healthydesign.com/products/bambach/BSSdownloads/BSS-dentist.pdf, Accessed on: 2010-07-20
*** Back Care for Dentists and Surgeons,
http://www.spineuniverse.com/wellness/ergonomics/backcare-dentists-surgeons, Accesed on: 2010-07-20
*** A Study of Back Pain In Dentistry,
https://dspace.gla.ac.uk/bitstream/1905/499/1/Church_Cairns.pdf, Accesed
on: 2010-07-20
*** Biomechanics Of Vertebral Manipulations In Chronic Low Back
Pain, http://www.plasma.uaic.ro/COMB/analele%20stintifice/2005/22_ailoaie_biomech anics.pdf, Accesed on: 2010-07-20
