Spiritual Well-Being in People Living with Persistent Non-Cancer and Cancer-Related Pain.

CONTEXT: Existential and spiritual factors are known to play an important role in how people cope with disability and life-threatening illnesses such as cancer. However, comparatively little is known about the impact of pain on factors such as meaning and purpose in one's life and their potential roles in coping with pain. OBJECTIVES: The aim of this study was to determine spiritual well-being scores in people with persistent pain and to compare these with people with cancer and healthy controls. METHODS: We assessed 132 people with chronic pain, 74 people with cancer (49 with pain and 25 without pain) and 68 control participants using standardised measures of pain-related variables including pain intensity, physical function, mood and cognitions. Spiritual well-being was also assessed using a validated and widely used questionnaire, the Functional Assessment of Chronic Illness Therapy - Spirituality Scale (FACIT-Sp). RESULTS: Spiritual well-being scores were significantly lower in people with persistent pain when compared with controls and were no different when compared with people with cancer, including those who had cancer and pain. In addition, low levels of meaning and purpose were significant predictors of depression, anxiety, and stress across all groups. CONCLUSION: The findings demonstrate that persistent pain is associated with spiritual distress that is equal to those observed in people who have cancer. Furthermore, those who have higher levels of meaning and purpose are less likely to develop mood dysfunction when experiencing pain, indicating they may have a protective role.

Spirituality: what is its role in pain medicine?

BACKGROUND: For many years, spirituality has been regarded as an integral aspect of patient care in fields closely allied to pain medicine such as palliative and supportive care. Despite this, it has received relatively little attention within the field of pain medicine itself. Reasons for this may include a lack of understanding of what spirituality means, doubtfulness of its relevance, an uncertainty about how it may be addressed, or a lack of awareness of how addressing spirituality may be of benefit. METHODS: A review of the literature was conducted to determine the changing conceptual frameworks that have been applied to pain medicine, the emergence of the biopsychospiritual approach and what that means as well as evidence for the benefits of incorporation of this approach for the management of pain. RESULTS: Although the concept of spirituality is broad, there is now greater consensus on what is meant by this term. Many authors and consensus panels have explored the concept and formulated a conceptual framework and an approach that is inclusive, accessible, relevant, and applicable to people with a wide range of health conditions. In addition, there is accumulating evidence that interventions that address the issue of spirituality have benefits for physical and emotional health. CONCLUSIONS: Given the firm place that spirituality now holds within other fields and the mounting evidence for its relevance and benefit for people with pain, there is increasing evidence to support the inclusion of spiritual factors as an important component in the assessment and treatment of pain.

Neuro magnetic resonance spectroscopy using wavelet decomposition and statistical testing identifies biochemical changes in people with spinal cord injury and pain.

Spinal cord injury (SCI) can be accompanied by chronic pain, the mechanisms for which are poorly understood. Here we report that magnetic resonance spectroscopy measurements from the brain, collected at 3T, and processed using wavelet-based feature extraction and classification algorithms, can identify biochemical changes that distinguish control subjects from subjects with SCI as well as subdividing the SCI group into those with and without chronic pain. The results from control subjects (n=10) were compared to those with SCI (n=10). The SCI cohort was made up of subjects with chronic neuropathic pain (n=5) and those without chronic pain (n=5). The wavelet-based decomposition of frequency domain MRS signals employs statistical significance testing to identify features best suited to discriminate different classes. Moreover, the features benefit from careful attention to the post-processing of the spectroscopy data prior to the comparison of the three cohorts. The spectroscopy data, from the thalamus, best distinguished control subjects without SCI from those with SCI with a sensitivity and specificity of 0.9 (Percentage of Correct Classification). The spectroscopy data obtained from the prefrontal cortex and anterior cingulate cortex both distinguished between SCI subjects with chronic neuropathic pain and those without pain with a sensitivity and specificity of 1.0. In this study, where two underlying mechanisms co-exist (i.e. SCI and pain), the thalamic changes appear to be linked more strongly to SCI, while the anterior cingulate cortex and prefrontal cortex changes appear to be specifically linked to the presence of pain.

Brain circuitry underlying pain in response to imagined movement in people with spinal cord injury.

Pain following injury to the nervous system is characterized by changes in sensory processing including pain. Although there are many studies describing pain evoked by peripheral stimulation, we have recently reported that pain can be evoked in subjects with complete spinal cord injury (SCI) during a motor imagery task. In this study, we have used functional magnetic resonance imaging to explore brain sites underlying the expression of this phenomenon. In 9 out of 11 subjects with complete thoracic SCI and below-level neuropathic pain, imagined foot movements either evoked pain in a previously non-painful region or evoked a significant increase in pain within the region of on-going pain (3.2+/-0.7-5.2+/-0.8). In both controls (n=19) and SCI subjects, movement imagery evoked signal increases in the supplementary motor area and cerebellar cortex. In SCI subjects, movement imagery also evoked increases in the left primary motor cortex (MI) and the right superior cerebellar cortex. In addition, in the SCI subjects, the magnitude of activation in the perigenual anterior cingulate cortex and right dorsolateral prefrontal cortex was significantly correlated with absolute increases in pain intensity. These regions expanded to include right and left anterior insula, supplementary motor area and right premotor cortex when percentage change in pain intensity was examined. This study demonstrates that in SCI subjects with neuropathic pain, a cognitive task is able to activate brain circuits involved in pain processing independently of peripheral inputs.

Differences in metabolites in pain-processing brain regions in patients with diabetes and painful neuropathy.

OBJECTIVE: Magnetic resonance spectroscopy (MRS) (specifically, (1)H-MRS) has been used to show changes in the brain following peripheral nerve injury in subjects without diabetes. This study used (1)H-MRS to examine the brain in subjects with or without painful diabetic neuropathy. RESEARCH DESIGN AND METHODS: Twenty-six diabetic subjects (12 with and 14 without chronic neuropathic pain) were compared, with 18 subjects without diabetes and pain. The left thalamus, anterior cingulate cortex (ACC), and dorsolateral prefrontal cortex (DLPFC) were assessed using (1)H-MRS. RESULTS: In the DLPFC, diabetic subjects had a decrease in N-acetyl aspartate (NAA) and creatine relative to the control group. In the thalamus, there was a reduction of NAA in the diabetic group with pain compared with that in patients with diabetes and no pain. CONCLUSION: Subjects with diabetes have metabolite differences in the brain compared with control subjects. Subjects with painful neuropathy showed reduced NAA in the thalamus, which may explain the genesis of pain in some cases.

Movement imagery increases pain in people with neuropathic pain following complete thoracic spinal cord injury.

Spinal cord injury (SCI) results in deafferentation and the onset of neuropathic pain in a substantial proportion of people. Based on evidence suggesting motor cortex activation results in attenuation of neuropathic pain, we sought to determine whether neuropathic SCI pain could be modified by imagined movements of the foot. Fifteen subjects with a complete thoracic SCI (7 with below-level neuropathic pain and 8 without pain) were instructed in the use of movement imagery. Movement imagery was practiced three times daily for 7days. On the eighth day, subjects performed the movement imagery in the laboratory and recorded pain ratings during the period of imagined movement. Six out of 7 subjects with neuropathic pain reported an increase in pain during imagined movements from 2.9+/-0.7 during baseline to 5.0+/-1.0 during movement imagery (p<0.01). In SCI subjects without neuropathic pain, movement imagery evoked an increase in non-painful sensation intensity from a baseline of 1.9+/-0.7 to 4.8+/-1.3 during the movement imagery (p<0.01). Two subjects without a history of pain or non-painful phantom sensations had onset of dysesthesia while performing imagined movements. This study reports exacerbation of pain in response to imagined movements and it contrasts with reports of pain reduction in people with peripheral neuropathic pain. The potential mechanisms underlying this sensory enhancement with movement imagery are discussed.

Magnetic resonance spectroscopy detects biochemical changes in the brain associated with chronic low back pain: a preliminary report.

Magnetic resonance (MR) spectroscopy is a noninvasive technique that can be used to detect and measure the concentration of metabolites and neurotransmitters in the brain and other organs. We used in vivo (1)H MR spectroscopy in subjects with low back pain compared with control subjects to detect alterations in biochemistry in three brain regions associated with pain processing. A pattern recognition approach was used to determine whether it was possible to discriminate accurately subjects with low back pain from control subjects based on MR spectroscopy. MR spectra were obtained from the prefrontal cortex, anterior cingulate cortex, and thalamus of 32 subjects with low back pain and 33 control subjects without pain. Spectra were analyzed and compared between groups using a pattern recognition method (Statistical Classification Strategy). Using this approach, it was possible to discriminate between subjects with low back pain and control subjects with accuracies of 100%, 99%, and 97% using spectra obtained from the anterior cingulate cortex, thalamus, and prefrontal cortex, respectively. These results demonstrate that MR spectroscopy, in combination with an appropriate pattern recognition approach, is able to detect brain biochemical changes associated with chronic pain with a high degree of accuracy.