Does Spinal Manipulation Therapy Impact Lumbar Proprioception

Manual therapy is widely used by patients with back pain with about 75% of patients consulting either a chiropractor, physiotherapist or osteopath. Often used manual therapies include spinal manipulative therapy (SMT), which is recommended in several clinical guidelines for management of back pain, mostly for acute low back pain (LBP) but also for chronic LBP. Despite the clinical benefits of SMT, the mechanisms underlying its effectiveness are poorly understood. Several mechanisms of action have been proposed including biomechanical and neurophysiological effects observed on spinal and supraspinal levels with unclear relationship to potential analgesic effects. Furthermore, non-specific effects such as placebo effects can strongly influence treatment outcomes and are difficult to control as consensus is lacking regarding the "active" agent of SMT, making it challenging to design an adequately controlled and blinded study.

A potential biological mechanism underlying the effectiveness of SMT might be related to sustained changes in lumbar proprioceptive function following repeated mechanical pressure on spinal tissues. In support of this, evidence from animal studies indicates that SMT comparable forces applied to the spine increase the discharge frequency of proprioceptive afferents in anesthetized cats, pointing towards an immediate effect of SMT on the activity of proprioceptive afferents. Proprioception is sub-served by mechanoreceptors on superficial and deep tissues. Located in the muscle belly parallel to the extrafusal muscle fibers, muscle spindles represent the main transmitters of proprioceptive information. Proprioceptive deficits have been suggested to provoke LBP through sensorimotor incongruence, abnormal loading across joint surfaces, and spinal instability due to less finely tuned muscular control, potentially causing sensorimotor dysfunction and degenerative processes in spinal tissues. In humans, there is anecdotal evidence that an SMT-induced repetitive barrage of proprioceptive input results in pain reduction and improves perceived function that might help to prevent LBP. However, a potential sustained and specific effect of SMT on lumbar proprioceptive function has not been systematically tested.

How one can test lumbar proprioceptive function in humans? Impairments in lumbar proprioception have been reported in LBP patients but only in sitting positions and mostly using proxy measures of proprioceptive function such as joint repositioning sense (JRS) and threshold to detect passive motion (TTDPM). The validity of these measures has been questioned as they measure position- and velocity-related proprioceptive sensation and the JRS is additionally influenced by motor skills and memory effects. Proprioceptive function can also be tested by assessing balance control (postural sway). Balance control presupposes a complex interplay involving the precise integration of proprioceptive inputs and motor outputs that can be tracked by analyzing postural sway on a force plate, a methodology that has been often used to assess differences in balance control in many diseases and conditions, including LBP. However, postural sway has been shown to be insensitive to changes of lumbar proprioceptive function, perhaps because postural sway relies on afferent input from various body locations and tissues. This can be overcome with a more direct assessment of proprioceptive function, achieved by using vibrotactile stimulation in combination with balance control measures. Vibration applied at frequencies between 60-80Hz (and amplitudes between 0.5-1mm) to muscles can selectively disturb proprioceptive signaling (mediated through primary (Ia) and secondary (II) muscle spindle afferents), affecting balance control by provoking corrective movements, often assessed through changes of the center of pressure (COP) in anterior-posterior direction. When endogenous or environmental conditions change, as in the instance of vibrotactile stimulation applied to the muscle, the balance control system must identify and selectively focus on sensory inputs providing the most reliable information, a process called sensory reweighting. Under normal conditions and while standing on a stable surface, healthy individuals rely on proprioceptive signals originating from ankle and paraspinal muscles. In contrast, standing on an unstable support surface (e.g. foam pad) forces individuals to rely less on ankle proprioception while up-weighting proprioceptive signals from paraspinal muscles. Differences in proprioceptive reweighting have been observed between healthy subjects and LBP patients by applying paraspinal and ankle muscle vibrotactile stimulation during a balance control task. Namely, during vibrotactile stimulation, individuals with recurrent LBP demonstrated an increased reliance on ankle proprioceptive signals compared to healthy subjects who up-weighted the proprioceptive signals from the paraspinal muscles (while down-weighting those from the ankle muscle to control postural balance). Importantly, a more "ankle-focused" strategy while standing on a stable support surface seems to increase the risk for developing or having recurrences of mild LBP within a time period of two years in young healthy individuals.

To test potential specific and sustained effects of SMT on lumbar proprioceptive function, the investigators aim to 1) assess SMT-induced changes in proprioceptive weighting (PW) over a two-week period and 2) use a rigorously controlled approach to control for non-specific effects. The planned experiments will be performed in healthy subjects and chronic LBP patients. This will allow to draw conclusions w.r.t. an isolated effect of SMT on lumbar proprioceptive function, providing a clear mechanism for SMT-induced changes in sensorimotor function.