Achieving Correction of Postural Asymmetry With Lateral Trunk Supports

Achieving Correction of Postural Asymmetry With Lateral Trunk Supports

Published on Wed, 09/29/2021 - 11:04

Bridget Churchill

Clinical Educator and Occupational Therapist

This blog provides some detail on why we use lateral trunk supports, how they can be configured to provide a clinically appropriate solution, and an overview of the range of lateral trunk supports available from Spex to enable the correction of postural asymmetry.

Why Do We Need Lateral Trunk Supports?

Even after we have correctly supported and stabilised the pelvis in sitting, the trunk may require additional support to withstand the effects of gravity, reduce fatigue and effort of sitting, and maintain an optimal position to support arm use and freedom of movement at the head and neck. Postural asymmetry requires reinforced support and stability – the trunk is no different. The spinal column and musculature are what hold our trunk upright above our pelvis against gravity. The spine transfers the load from the head and trunk to the pelvis and allows movement in the sagittal plane (flexion and extension), frontal/coronal plane (abduction and adduction) and transverse plane (rotation). The spinal column alignment can change due to neurological conditions and/or trauma.

Image Source: Wikipedia

One common condition that affects this alignment of the spinal column is scoliosis, which can occur at any age and be linked to congenital, neurological or idiopathic (unknown) origins. To an observer, a person with scoliosis may present with uneven shoulders, uneven shoulder blades (scapulae), uneven pelvis (with one side lower than the other, known as pelvic obliquity) and a rotated or side-ways bend in the spine. The sideways curves that are created – these can be either a C or S-shape – lead to changes in muscular activity and orthopaedic alignment. Posture becomes less efficient and more effortful. When we think about the planes of movement you might see:

Coronal/Frontal PlaneLateral trunk flexion (sideways bend)
Transverse PlaneRotation/twisting of the vertebrae or pelvis.
Sagittal PlaneHyper-/hypokyphosis (severe or flattened thoracic spinal curve)
Hyper-/hypolordosis (severe or flattened lordotic spinal curve)
Flat back (spinal curves absent or significantly reduced)

When any of this asymmetry is present, it can change where the back contacts the wheelchair back support. This, in turn, affects weight distribution and stability, which is why lateral trunk supports may be required for additional support in the seated position

Figure 1 Scoliosis affects the symmetry between left and right sides of the trunk and can add to exaggerated lumbar or thoracic curves. 

 

“While, according to Newton’s Law of Gravity, we can predict where the apple that falls from a tree will land, we cannot similarly predict where a leaf that falls from a tree will land. The tree leaf falls according to the same laws, but the precise location of its landing remains unpredictable because the leaf is more sensitive to the wind. This type of unpredictability also defines the development and progression of scoliosis in an individual.”
(Berdishevsky et al., 2016)
 

Scoliosis can also be influenced by the alignment of the pelvis (see below). In the presence of pelvic obliquity, the spine and trunk muscles will need to adjust and respond to maintain stability. When a wheelchair user has weakened muscles or fatigue, this can exaggerate the instability they experience in sitting with an increased likelihood that they will begin to lean to the side or need to prop on their arms in order to maintain equilibrium.  Therefore, we need to ensure the pelvis is as symmetrical (level/neutral) as possible to eliminate secondary trunk and spine asymmetries in sitting.

 

Figure 2 Here I demonstrate a passive (created) right obliquity of the pelvis (right side lower) by adding a build-up under the left ischial tuberosity of the pelvis: (LEFT) neutral pelvic position with pelvis neutral in coronal, sagittal and transverse planes, (CENTRE) mild right obliquity with 1.5cm build-up under left side of pelvis, (RIGHT) increased right pelvic obliquity with 3cm build up under left side of pelvis.

 

Figure 3 Here I demonstrate how the same changes in Figure 2 might affect alignment of the trunk and spine: (LEFT) neutral pelvic position with pelvis neutral in coronal, sagittal and transverse planes, (CENTRE) right pelvic obliquity (lower) that is beginning to create a  convex curve of the trunk and some minimal trunk rotation to the left as I try to maintain stability, (RIGHT) Increased right pelvic obliquity that has resulted in exaggerated right convex curve of the trunk, some pelvic rotation to the right and trunk rotation to the left as I try to maintain my stability.

 

Our bodies will naturally adapt and respond to pelvic asymmetry. Figure 2 and Figure 3 are examples of how my body responded to the increased instability caused by a pelvic obliquity. The type of lateral trunk support selected depends on the presenting postural asymmetry and functional need. If you try to copy the postures above, you will feel how effortful sitting becomes. This can cause fatigue, create pain or increased pressure to weight-bearing surfaces, reduce sitting tolerance and lead to awkward posturing during engagement in activities as the body tries not to fall over. Wheelchair prescribers seek to optimise pelvic (and other body segment) alignment and reduce the effort of sitting so that wheelchair users are physically able to engage in their activities and function whilst seated in the wheelchair.

Lateral trunk supports can help reinforce support when there is asymmetry by:

  • Reducing the severity of leaning to the side by supporting the trunk (in the case of a reducible asymmetry) by optimising alignment.
  • Blocking the direction of undesirable movement to reduce secondary postural deformity.
  • Providing additional support to the trunk against gravity to reduce the effort of sitting.

You may have heard clinicians talk about 3-points of control, which simply refers to the biomechanical response to a c-shaped curve where supports are placed to prevent the curve from getting any worse. The curve is blocked at the ends of the curve and at the apex of the curve. By applying force, the C-shape may be reduced. Using this principle, we use lateral supports to support and/or reduce spinal curves to prevent the C-shape from increasing. This is illustrated in the figure below.

Figure 4 Here I demonstrate how lateral trunk supports can be used to provide three points of control (red arrows) to respond to the spinal curve to the left. Key to remember is that the pelvis must also be stabilised. The blue line indicates the line of gravity that is a constant force on the body pressing vertically down. The yellow line indicates the reactive force performed by the cushion or seating surface.  We need to consider the body’s centre of mass – the point at which the all the forces are applied and equilibrium has occurred. Equilibrium may be unachievable for some wheelchair users where muscles and alignment make it too effortful to maintain without posterior (back) or lateral (side) support.

 

Who Might Need Lateral Trunk Supports?

An active user may require lateral support for stability and orientation of the trunk whilst they self-propel the wheelchair. The lateral supports may need to be easily removable for ease of transfers (such as swing-away mechanisms) and may allow the wheelchair user to easily move forwards from the back support for functional activities without restrictions (such as with flat lateral trunk support pads that do not curve around the trunk). A prop-sitter, someone who requires propping on their hand(s) to maintain sitting balance, may require lateral supports for stability and reinforced support due to muscle weakness, scoliosis or trunk rotation to be able to use their hand(s) for function. Support pads may need to be curved to better distribute pressure and meet the contours of the body. Some wheelchair users cannot use their arms to support themselves.  They would require lateral supports for reasons explained above and to ensure that the body is sufficiently supported against gravity to allow them to sit without collapsing. Support pads and hardware may need to be able to respond to more complex positions against the trunk to provide stability and comfort.

What Must We Consider When Choosing Lateral Trunk Supports?

The weight/force that is placed on the lateral trunk support needs to be considered as this may require careful choice of padding and lateral trunk support pad size selection.

  • Increased weight or leaning against the trunk supports requires a trunk support pad with a larger surface area.
  • The area in contact with the trunk support may require a contoured support pad for pressure distribution and optimal contact with the body.
  • Bodies with bony prominences (such as protruding rib bones or rib flaring) may require trunk support pads with improved pressure-relieving and contouring properties.

The direction of force placed on the lateral trunk support needs to be considered.

  • Bodies with sharp convex or concave lateral curves (such as with scoliosis) may require support pads that can respond to angled contours and provide multi-directional support.
  • If the trunk is leaning to the side and lowering in response to gravity, the lateral trunk support needs to counter this by providing lateral and upward directional support.
  • If the pelvis migrates sideways and upwards due to obliquity or scoliosis, the trunk support may need to respond by blocking further pelvic migration in a lateral and downward direction.
  • If asymmetry results in the body falling sideways, the trunk support needs to provide lateral support to block this ‘falling.’

Because body shapes are unique, trunk support pads need to be able to respond to each person. For this reason, they range from small to big, narrow to broad, and curved to flat. Where the support pad meets the body is critical – the hardware selected is as important as the pad selection and needs to take the following into account:

  • Distance from the back shell.
  • Placement inside / outside of the back shell (e.g., width adjustment).
  • Height from the seat and distance from the axillae (under-arm) – if the lateral trunk support is placed in the underarm crease this can cause pressure injuries and nerve compression so care must be taken.

 

What Lateral Trunk Supports Are Offered by Spex?

FixedAxial Swing-AwayStandard Swing-AwayQuick Release 
Figure 5 Examples of Spex hardware for the lateral trunk support pads

 

Figure 6 Examples of Spex hardware to ensure that the lateral support pad is able to reach the wheelchair user’s body in the correct position. These include straight, off-set, cane-mounted, extended and reinforced options to meet particular user needs.

 

Figure 7 Examples of Spex pad sizes and adjustments possible within the Spex hardware and pad combinations.

 

Figure 8 An example of how the Spex swing-away laterals can provide posterior-lateral or lateral-anterior support to respond to unique trunk asymmetry and shaping (left & centre), and how the axial technology allows pads to be angled upwards or downwards to support the lateral contours of the wheelchair user’s body (right).

 

Figure 9 Example of Spex modular lateral trunk supports for a wheelchair user with severe scoliosis. Including: new biangular lateral trunk supports, narrow contoured lateral support, axial hardware and the ability to offer multiple points of control and support for the trunk, in addition to the lateral axial hip/thigh supports and headrest for support at the pelvis and head, respectively.

 

Spex modular lateral trunk supports and pads can be mixed and matched according to clinical need, whether it be one or multiple supports required for an individual user.

Thank you for reading! We welcome comments and questions so please do leave a comment below.

 

References

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