SCS-OMICS: Transcriptomic Profile of Patients Treated With Different Modalities of Spinal Cord Stimulation

Study Description

Brief Summary

Failed Back Surgery Syndrome (FBSS) is a relatively common condition that can cause a severe disability in patients. Spinal cord stimulation (SCS) is used in those patients refractory to conventional therapies.In this project the investigators aim to identify new functional molecular basis, defined with transcriptomic profiling, differentially represented in the serum of patients suffering chronic pain caused by FBSS.

The investigators will try to Identify "omics" markers for diagnosing and monitoring the process of development and maintenance of pain as well as the evaluation of these as evolutionary disease markers or predictors of the response to SCS therapy. To carry out the project, 40 patients diagnosed with refractory FBSS and treated with an SCS system for pain management will be included. Blood samples will be obtained to analyze the transcription profiling in plasma of patients responding to different modalities of SCS therapy.

Detailed Description

Failed back surgery syndrome (FBSS) is a real challenge for the specialist because of its clinical complexity and economic importance not only in the cost of treatment but because of the high incidence of the syndrome in patients of working age and with normal life expectancy. This syndrome is a complication of lumbosacral surgery with an incidence ranging from 5-40%.

Spinal cord stimulation (SCS) has been used in the treatment of patients with FBSS for years safely and effectively . Although it was initially believed that the main mechanism of action was explained by the "Gate Control Theory" described by Wall and Melzack in 1965, it should be noted that other mechanisms beyond this could contribute to pain relief resulting from SCS. These include inhibition of neuronal excitability and hypersensitivity at the medullary level as well as changes in the release of neurotransmitters like GABA, acetylcholine, adenosine, serotonin and norepinephrine, involved in the transmission and modulation of pain. However, the molecular mechanisms underlying the therapeutic effect of SCS remain unknown.

Genetic studies are used to provide new insights into the molecular mechanisms underlying the onset and maintenance of pain. These can be driven by the hypothesis, thus evaluating the expression of default molecules, or independent of the hypothesis, exploring gene expression at the gene level at the whole genome. Microarray chips measure the expression of hundreds of genes in a given sample. Used to study a wide variety of biological systems, they have been used to evaluate extensive changes at the transcriptional level in different parts of the central or peripheral nervous system, leading to the discovery of new pain-related genes such as the Kv9.1 subunit of the potassium channel or KCNS1.

Recently, some animal model studies suggest that SCS produces extensive changes in gene expression. Tilley and collaborators found that SCS produced modulation in the expression of 5HTra, cFOS and GABAbr1 among others, with a strong correlation between the amount of current applied and the expression of GABAbr1, Na/K ATPase (negative correlation), 5HT3r and VIP (positive correlation) at the medular level and also at the level of the dorsal root ganglion. These authors focused on analyzing groups of genes that were shown altered in animal models of peripheral nerve injury. Stephens and collaborators performed an RNA seq of the spinal cord of rats with neuropathic pain secondary to the sciatic nerve ligation to which a spinal cord stimulator was implanted and found that gene expression changed after the application of SCS. They identified that the expression of some key genes in the expression of protein dense post-synaptic supporting proteins network in glutamaergic synapses is downregulated after SCS; this could destabilize this dense network, thus decreasing the effectiveness of synaptic signaling. They also found that SCS could activate nearby spinal tracts that affect neurons and gloss cells in the distal spinal segments. Vallejo and Tilley's group also performed extensive transcriptome analysis in animal models of neuropathic pain and found that SCS produces significant modulation in gene expression at the spinal cord and dorsal root ganglion level, with groups of genes and metabolic pathways similar in both tissues and which are directly or indirectly related to neural regeneration, regulation of inflammatory and immune responses and regulation of ion transport. Our group analyzed the gene expression of different markers (from cannabinoid receptors, opioid receptors and opioid peptides) using real-time polymerase chain reaction from lymphocyte RNA obtained from peripheral blood samples of patients with FBSS treated with SCS, observing a significant increase in proenkephalin (PNK) following SCS with respect to baseline levels and maintained over time.

Using the advantages of large-scale study of the genome using microarrays, we have carried out a research project in recent years with the main objective of identifying new molecular bases, defined with transcriptomic profiles, differentially expressed in the plasma of patients affected by FBSS and treated with tonic or conventional SCS. This study has been funded by Instituto de Salud Carlos III through the Project PI16/01364 (Co-funded by European Regional Development Fund/European Social Fund "A way to make Europe"/"Investing in your future"). The project was approved by the Ethical Committee for Clinical Research of the University General Hospital of Valencia. The study complied with local regulations, Good Clinical Practice guidelines, and the principles of the Declaration of Helsinki, as well as with current legislation and regulations governing protection of personal data and the rights and responsibilities regarding information and documentation in health care. Our group performed a transcriptomic analysis of the blood of patients affected of FBSS and treated with SCS (responder patients); we obtained samples before and at different times after implantation of the system in order to find differential gene expression in response to treatment and that could serve as potential biomarkers of effectiveness to therapy. We also performed transcriptomic analysis of patients in which SCS was not effective (non-responders), comparing the results with the responding patients with the intention of finding differential expression of potential biomarkers of response to SCS therapy. Finally, we compared the expression of patients diagnosed with FBSS with a group of spine-intervened patients who did not develop pain and served as a control group; we try to find differences in the gene expression between the two populations with the aim of finding possible biomarkers of disease development. We included 30 patients with SCS-treated FBSS (of whom 7 were non-responders and 23 responders) and 15 control patients. We have completed the recruitment and analysis of the samples periods and we are currently in the interpretation phase of the final results and development of the corresponding publications. Although the results are not definitive, preliminary analysis shows that there are more than 190 differentially expressed genes (p < 0.05) at baseline when comparing control patients and patients with FBSS treated with SCS. We also found more than 750 genes differentially expressed in patients implanted before and after the onset of SCS therapy.

HYPOTHESIS

The biochemical and molecular processes associated with FBSS are unknown as are the changes that occur in patients undergoing SCS. The transcriptomic analysis seem promising tools to provide insight on the mechanisms underlying chronic pain. Quantification of RNA with RT-PCR will allow to identify differential genes implicated and solid conclusions to be drawn.

Our hypothesis is based on the fact that different genetic expression must occur in clinical situations related to pain and that these alterations should be differentially modified in patients successfully treated with spinal cord stimulation.

The identification of these possible biomarkers of state or evolution of the pathology and its treatment will contribute significantly to establish more accurate therapeutic strategies and can serve as predictive biomarkers of response to treatment, guiding the selection of therapeutic targets for the development of future treatment strategies.

AIMS OF THE STUDY

Based on these hypotheses and with the hopeful results previously obtained by our group, the investigators aim to compare whether the DTM programming of the SCS system produces a different expression-level effect than conventional programming with the intention of seeking biomarkers of response and evolution to this programming modality.

The investigators also aim to study whether these differences could be in relation to significantly different clinical outcomes and correlate with the intensity of the effect of the different modalities.

Study Design

Outcome Measures

Primary Outcome Measures

1. Transcriptomic profile change in DTM responders [T0: Before IPG; T1: 15 days after IPG and T2 2 months after IPG]

   Identify the transcriptomic signature of responding patients undergoing DTM programming of the SCS system and analyze potential changes over time

Secondary Outcome Measures

1. DTM vs Conventional signatures [T0: Before IPG; T1: 15 days after IPG and T2 2 months after IPG]

   Compare whether the DTM programming of the SCS system produces a different expression-level effect than conventional programming

2. Transcriptomic Profile vs Clinical Outcomes [T0: Before IPG; T1: 15 days after IPG and T2 2 months after IPG]

   Analyze potential correlations between the transcriptomic profiles measured wiht RNAseq techniques with clinical measurements (Intensity of pain measured with Numeric Rating Scale and level of disability measured with Oswestry Scale

3. Intensity of pain [T0: Before IPG; T1: 15 days after IPG and T2 2 months after IPG]

   Measure the intensity of pain with a Numeric Rating Scale (NRS) in different moments before and after the treatment with SCS

4. QOL [T0: Before IPG; T1: 15 days after IPG and T2 2 months after IPG]

   Measure the quality of life of patients with FBSS who undergo treatment with a spinal cord stimulation system with the SF12 questionnaire in different moments before and after the treatment with SCS

5. Level of disability [T0: Before IPG; T1: 15 days after IPG and T2 2 months after IPG]

   Measure the Level of disability of patients with FBSS who undergo treatment with a spinal cord stimulation system with the Oswestry Score in different moments before and after the treatment with SCS

Eligibility Criteria

Criteria

Inclusion Criteria:

• Adult patients affected by FBSS, defined as "surgical end stage after one or several interventions on the lumbar neuroaxis indicated to relief lower back pain, root pain or the combination of both, without effect"

• Age between 18 and 65 years

• Severe pain measured on a numerical rating scale (NRS > 6/10), more than six months of evolution

• Refractory pain despite having carried out pharmacological treatment according to WHO's stratified approach; physical/rehabilitation therapy and/or interventional procedures (e.g. epidural steroid injections, radiofrequency, epiduroscopy/adhesiolysis)

Exclusion Criteria:

• Patients with severe associated comorbidities (e.g. severe high blood pressure, diabetes mellitus, peripheral vasculopathy, severe heart disease, etc...) that may in themselves cause pain or aggravate the existence of previous pain.

• Extensive osteosynthesis encompassing the thoraco-lumbar region where the tips of the electrodes are routinely positioned.

• Abnormal pain behavior, unresolved psychiatric illness, unresolved issues of secondary gain or inappropriate medication use

• Patients not consenting or refusing to participate will be excluded

• Negative evaluation of the psychologist previous to the implant

Contacts and Locations

Locations

Sponsors and Collaborators

• Hospital General Universitario de Valencia

Investigators

• Principal Investigator: Gustavo Fabregat, MD, PhD, Consultant of Anesthesiology and Pain Medicine Department

Study Documents (Full-Text)

More Information

Publications

• Chan CW, Peng P. Failed back surgery syndrome. Pain Med. 2011 Apr;12(4):577-606. doi: 10.1111/j.1526-4637.2011.01089.x. Epub 2011 Apr 4.
• Costigan M, Belfer I, Griffin RS, Dai F, Barrett LB, Coppola G, Wu T, Kiselycznyk C, Poddar M, Lu Y, Diatchenko L, Smith S, Cobos EJ, Zaykin D, Allchorne A, Gershon E, Livneh J, Shen PH, Nikolajsen L, Karppinen J, Mannikko M, Kelempisioti A, Goldman D, Maixner W, Geschwind DH, Max MB, Seltzer Z, Woolf CJ. Multiple chronic pain states are associated with a common amino acid-changing allele in KCNS1. Brain. 2010 Sep;133(9):2519-27. doi: 10.1093/brain/awq195. Epub 2010 Aug 18. Erratum In: Brain. 2011 Jul;134(7):2186. Gershon, Edith [added]; Livneh, Jessica [added].
• Cui JG, Meyerson BA, Sollevi A, Linderoth B. Effect of spinal cord stimulation on tactile hypersensitivity in mononeuropathic rats is potentiated by simultaneous GABA(B) and adenosine receptor activation. Neurosci Lett. 1998 May 15;247(2-3):183-6. doi: 10.1016/s0304-3940(98)00324-3.
• Cui JG, O'Connor WT, Ungerstedt U, Linderoth B, Meyerson BA. Spinal cord stimulation attenuates augmented dorsal horn release of excitatory amino acids in mononeuropathy via a GABAergic mechanism. Pain. 1997 Oct;73(1):87-95. doi: 10.1016/s0304-3959(97)00077-8.
• De Andres J, Monsalve-Dolz V, Fabregat-Cid G, Villanueva-Perez V, Harutyunyan A, Asensio-Samper JM, Sanchis-Lopez N. Prospective, Randomized Blind Effect-on-Outcome Study of Conventional vs High-Frequency Spinal Cord Stimulation in Patients with Pain and Disability Due to Failed Back Surgery Syndrome. Pain Med. 2017 Dec 1;18(12):2401-2421. doi: 10.1093/pm/pnx241.
• De Andres J, Navarrete-Rueda F, Fabregat G, Garcia-Gutierrez MS, Monsalve-Dolz V, Harutyunyan A, Minguez-Marti A, Rodriguez-Lopez R, Manzanares J. Differences in Gene Expression of Endogenous Opioid Peptide Precursor, Cannabinoid 1 and 2 Receptors and Interleukin Beta in Peripheral Blood Mononuclear Cells of Patients With Refractory Failed Back Surgery Syndrome Treated With Spinal Cord Stimulation: Markers of Therapeutic Outcomes? Neuromodulation. 2021 Jan;24(1):49-60. doi: 10.1111/ner.13111. Epub 2020 Feb 6.
• Gonzalez Viejo MA, Condon Huerta MJ. [Disability from low back pain in Spain]. Med Clin (Barc). 2000 Apr 8;114(13):491-2. doi: 10.1016/s0025-7753(00)71342-x. Spanish.
• Guan Y, Wacnik PW, Yang F, Carteret AF, Chung CY, Meyer RA, Raja SN. Spinal cord stimulation-induced analgesia: electrical stimulation of dorsal column and dorsal roots attenuates dorsal horn neuronal excitability in neuropathic rats. Anesthesiology. 2010 Dec;113(6):1392-405. doi: 10.1097/ALN.0b013e3181fcd95c.
• Gybels J, Erdine S, Maeyaert J, Meyerson B, Winkelmuller W, Augustinsson L, Bonezzi C, Brasseur L, DeJongste M, Kupers R, Marchettini P, Muller-Schwefe G, Nitescu P, Plaghki L, Reig E, Spincemaille G, Thomson S, Tronnier V, Van Buyten JP. Neuromodulation of pain. A consensus statement prepared in Brussels 16-18 January 1998 by the following task force of the European Federation of IASP Chapters (EFIC). Eur J Pain. 1998;2(3):203-9. doi: 10.1016/s1090-3801(98)90016-7. No abstract available.
• Inoue S, Kamiya M, Nishihara M, Arai YP, Ikemoto T, Ushida T. Prevalence, characteristics, and burden of failed back surgery syndrome: the influence of various residual symptoms on patient satisfaction and quality of life as assessed by a nationwide Internet survey in Japan. J Pain Res. 2017 Apr 6;10:811-823. doi: 10.2147/JPR.S129295. eCollection 2017.
• Kumar K, Taylor RS, Jacques L, Eldabe S, Meglio M, Molet J, Thomson S, O'Callaghan J, Eisenberg E, Milbouw G, Buchser E, Fortini G, Richardson J, North RB. Spinal cord stimulation versus conventional medical management for neuropathic pain: a multicentre randomised controlled trial in patients with failed back surgery syndrome. Pain. 2007 Nov;132(1-2):179-88. doi: 10.1016/j.pain.2007.07.028. Epub 2007 Sep 12.
• LaCroix-Fralish ML, Austin JS, Zheng FY, Levitin DJ, Mogil JS. Patterns of pain: meta-analysis of microarray studies of pain. Pain. 2011 Aug;152(8):1888-1898. doi: 10.1016/j.pain.2011.04.014. Epub 2011 May 10.
• Linderoth B, Foreman RD. Conventional and Novel Spinal Stimulation Algorithms: Hypothetical Mechanisms of Action and Comments on Outcomes. Neuromodulation. 2017 Aug;20(6):525-533. doi: 10.1111/ner.12624. Epub 2017 May 31.
• Linderoth B, Gazelius B, Franck J, Brodin E. Dorsal column stimulation induces release of serotonin and substance P in the cat dorsal horn. Neurosurgery. 1992 Aug;31(2):289-96; discussion 296-7. doi: 10.1227/00006123-199208000-00014.
• Melzack R, Wall PD. Pain mechanisms: a new theory. Science. 1965 Nov 19;150(3699):971-9. doi: 10.1126/science.150.3699.971. No abstract available.
• Monsalve V, de Andres JA, Valia JC. Application of a psychological decision algorithm for the selection of patients susceptible to implantation of neuromodulation systems for the treatment of chronic pain. A proposal. Neuromodulation. 2000 Oct;3(4):191-200. doi: 10.1046/j.1525-1403.2000.00191.x.
• North RB, Wetzel FT. Spinal cord stimulation for chronic pain of spinal origin: a valuable long-term solution. Spine (Phila Pa 1976). 2002 Nov 15;27(22):2584-91; discussion 2592. doi: 10.1097/00007632-200211150-00035.
• Sakai A, Suzuki H. Emerging roles of microRNAs in chronic pain. Neurochem Int. 2014 Nov;77:58-67. doi: 10.1016/j.neuint.2014.05.010. Epub 2014 Jun 3.
• Schechtmann G, Song Z, Ultenius C, Meyerson BA, Linderoth B. Cholinergic mechanisms involved in the pain relieving effect of spinal cord stimulation in a model of neuropathy. Pain. 2008 Sep 30;139(1):136-145. doi: 10.1016/j.pain.2008.03.023. Epub 2008 May 9.
• Shechter R, Yang F, Xu Q, Cheong YK, He SQ, Sdrulla A, Carteret AF, Wacnik PW, Dong X, Meyer RA, Raja SN, Guan Y. Conventional and kilohertz-frequency spinal cord stimulation produces intensity- and frequency-dependent inhibition of mechanical hypersensitivity in a rat model of neuropathic pain. Anesthesiology. 2013 Aug;119(2):422-32. doi: 10.1097/ALN.0b013e31829bd9e2.
• Stiller CO, Cui JG, O'Connor WT, Brodin E, Meyerson BA, Linderoth B. Release of gamma-aminobutyric acid in the dorsal horn and suppression of tactile allodynia by spinal cord stimulation in mononeuropathic rats. Neurosurgery. 1996 Aug;39(2):367-74; discussion 374-5. doi: 10.1097/00006123-199608000-00026.
• Taylor RS, Taylor RJ. The economic impact of failed back surgery syndrome. Br J Pain. 2012 Nov;6(4):174-81. doi: 10.1177/2049463712470887.
• Tilley DM, Cedeno DL, Kelley CA, Benyamin R, Vallejo R. Spinal Cord Stimulation Modulates Gene Expression in the Spinal Cord of an Animal Model of Peripheral Nerve Injury. Reg Anesth Pain Med. 2016 Nov/Dec;41(6):750-756. doi: 10.1097/AAP.0000000000000452.
• Tilley DM, Cedeno DL, Kelley CA, DeMaegd M, Benyamin R, Vallejo R. Changes in Dorsal Root Ganglion Gene Expression in Response to Spinal Cord Stimulation. Reg Anesth Pain Med. 2017 Mar/Apr;42(2):246-251. doi: 10.1097/AAP.0000000000000550.
• Tsantoulas C, Zhu L, Shaifta Y, Grist J, Ward JP, Raouf R, Michael GJ, McMahon SB. Sensory neuron downregulation of the Kv9.1 potassium channel subunit mediates neuropathic pain following nerve injury. J Neurosci. 2012 Nov 28;32(48):17502-13. doi: 10.1523/JNEUROSCI.3561-12.2012.
• Turner JA, Loeser JD, Deyo RA, Sanders SB. Spinal cord stimulation for patients with failed back surgery syndrome or complex regional pain syndrome: a systematic review of effectiveness and complications. Pain. 2004 Mar;108(1-2):137-47. doi: 10.1016/j.pain.2003.12.016.
• Vallejo R, Tilley DM, Cedeno DL, Kelley CA, DeMaegd M, Benyamin R. Genomics of the Effect of Spinal Cord Stimulation on an Animal Model of Neuropathic Pain. Neuromodulation. 2016 Aug;19(6):576-86. doi: 10.1111/ner.12465. Epub 2016 Jul 8.
• Vallejo R, Tilley DM, Williams J, Labak S, Aliaga L, Benyamin RM. Pulsed radiofrequency modulates pain regulatory gene expression along the nociceptive pathway. Pain Physician. 2013 Sep-Oct;16(5):E601-13.
• Van Buyten JP. Neurostimulation for chronic neuropathic back pain in failed back surgery syndrome. J Pain Symptom Manage. 2006 Apr;31(4 Suppl):S25-9. doi: 10.1016/j.jpainsymman.2005.12.012.
• Yang F, Xu Q, Cheong YK, Shechter R, Sdrulla A, He SQ, Tiwari V, Dong X, Wacnik PW, Meyer R, Raja SN, Guan Y. Comparison of intensity-dependent inhibition of spinal wide-dynamic range neurons by dorsal column and peripheral nerve stimulation in a rat model of neuropathic pain. Eur J Pain. 2014 Aug;18(7):978-88. doi: 10.1002/j.1532-2149.2013.00443.x. Epub 2014 Jan 6.
• Zhang TC, Janik JJ, Grill WM. Mechanisms and models of spinal cord stimulation for the treatment of neuropathic pain. Brain Res. 2014 Jun 20;1569:19-31. doi: 10.1016/j.brainres.2014.04.039. Epub 2014 May 4.
• Zhang TC, Janik JJ, Peters RV, Chen G, Ji RR, Grill WM. Spinal sensory projection neuron responses to spinal cord stimulation are mediated by circuits beyond gate control. J Neurophysiol. 2015 Jul;114(1):284-300. doi: 10.1152/jn.00147.2015. Epub 2015 May 13.