Acute pain after serratus anterior plane or thoracic paravertebral blocks for video-assisted thoracoscopic surgery: A noninferiority randomised trial.

BACKGROUND: Serratus anterior plane blocks (SAPBs) and thoracic paravertebral blocks (TPVBs) can both be used for video-assisted thoracic surgery. However, it remains unknown whether the analgesic efficacy of a SAPB is comparable to that of a TPVB. OBJECTIVE: We tested the primary hypothesis that SAPBs provide noninferior analgesia compared with TPVBs for video-assisted thoracic surgery. DESIGN: A noninferiority randomised trial. SETTING: Shanghai Chest Hospital, between August 2018 and November 2018. PATIENTS: Ninety patients scheduled for video-assisted thoracic lobectomy or segmentectomy were randomised. Patients were excluded if they were unable to perform the visual analogue pain scale, or surgery was converted to thoracotomy. INTERVENTIONS: Blocks were performed after induction of general anaesthesia. The three groups were paravertebral blocks (n = 30); serratus anterior plane blocks (n = 29); and general anaesthesia alone (n = 30). PRIMARY OUTCOME MEASURES: Visual analogue pain scores (0 to 10 cm) at rest and while coughing, and Prince-Henry pain scores (0 to 4 points) were used to assess postoperative analgesia at 2, 24 and 48 h after surgery. We assessed the noninferiority of SAPBs with TPVBs on all three primary pain outcomes using a delta of 1 cm or one point as appropriate. RESULTS: The mean difference (95% confidence intervals) in visual analogue scores between the SAPBs and TPVBs was -0.04 (-0.10 to 0.03) cm at rest, -0.22 (-0.43 to -0.01) cm during coughing and -0.10 (-0.25 to 0.05) for Prince-Henry pain scores. As the upper limit of the confidence intervals were less than 1 (all P < 0.001), noninferiority was claimed for all three primary outcomes. Compared with general anaesthesia alone, the VAS scores at rest and while coughing, and the Prince-Henry pain scores for the two blocks were significantly lower during the initial 2 h after surgery. CONCLUSIONS: Serratus anterior plane blocks are quicker and easier to perform than paravertebral blocks and provide comparable analgesia in patients having video-assisted thoracic surgery. Both blocks provided analgesia that was superior to general anaesthesia alone during the initial 2 h after surgery. TRIAL REGISTRATION: Chinese Clinical Trial Registry, identifier: ChiCTR1800017671.

Acute pain after serratus anterior plane or thoracic paravertebral blocks for video-assisted thoracoscopic surgery: A randomised trial.

BACKGROUND: Serratus anterior and paravertebral blocks can both be used for video-assisted thoracic surgery. However, serratus anterior blocks are easier to perform, and possibly safer. We therefore tested the primary hypothesis that serratus anterior plane blocks and thoracic paravertebral blocks provide comparable analgesia for video-assisted thoracic surgery. Secondarily, we tested the hypothesis that both blocks lengthen the time to onset of surgical pain and reduce the need for rescue tramadol. METHODS: Patients having video-assisted thoracic lobectomy or segmentectomy were randomly allocated to ultrasound-guided thoracic paravertebral blocks, n = 30; ultrasound-guided serratus anterior plane blocks, n = 30; or, general anaesthesia alone, n = 30. Visual analogue pain scores analogue pain scores at rest, during coughing and Prince-Henry pain scores were used to assess postoperative analgesia. Our primary analysis was noninferiority of serratus anterior blocks compared with paravertebral blocks. RESULTS: Baseline characteristics were comparable among the three groups. Two hours after surgery, the mean difference in visual analogue pain scores between the serratus anterior and paravertebral blocks was 0.0 (96.8% CI -0.4 to 0.3) cm at rest, -0.2 (-0.8 to 0.4) cm during coughing and -0.1(-0.5 to 0.3) for Prince-Henry pain scores. After 24 h, the mean difference was 0.0 (-0.7 to 0.8) cm at rest, 0.1 (-0.8 to 0.9) cm during coughing and 0.1(-0.4 to 0.6) for Prince-Henry pain scores. All differences were significantly noninferior. Time to onset of pain after surgery was 19 ±â€Š5 (SD) hours with serratus anterior blocks, 16 ±â€Š5 h with paravertebral blocks and 12 ±â€Š5 h with general anaesthesia. Anaesthesia with either block was associated with significantly less intra-operative propofol and sufentanil, reduced postoperative rescue analgesia (tramadol) and less postoperative nausea and vomiting compared with general anaesthesia alone. Patients with serratus anterior block had a significantly lower incidence of intra-operative hypotension and requirement for intra-operative vasopressor (3.4%), compared with general anaesthesia alone. Serratus anterior block took less time to perform than paravertebral block (5.1 ±â€Š1.1 min versus 10.1 ±â€Š2.9 min). CONCLUSION: Serratus anterior plane blocks, which are easier and quicker than paravertebral blocks, provide comparable analgesia in patients having video-assisted thoracic surgery. CLINICAL TRIAL NUMBER AND REGISTRY URL: ChiCTR1800017671; http://www.chictr.org.cn/hvshowproject.aspx?id=13510.

Drosophila TRPML forms PI(3,5)P2-activated cation channels in both endolysosomes and plasma membrane.

Transient Receptor Potential mucolipin (TRPML) channels are implicated in endolysosomal trafficking, lysosomal Ca(2+) and Fe(2+) release, lysosomal biogenesis, and autophagy. Mutations in human TRPML1 cause the lysosome storage disease, mucolipidosis type IV (MLIV). Unlike vertebrates, which express three TRPML genes, TRPML1-3, the Drosophila genome encodes a single trpml gene. Although the trpml-deficient flies exhibit cellular defects similar to those in mammalian TRPML1 mutants, the biophysical properties of Drosophila TRPML channel remained uncharacterized. Here, we show that transgenic expression of human TRPML1 in the neurons of Drosophila trpml mutants partially suppressed the pupal lethality phenotype. When expressed in HEK293 cells, Drosophila TRPML was localized in both endolysosomes and plasma membrane and was activated by phosphatidylinositol 3,5-bisphosphate (PI(3,5)P2) applied to the cytoplasmic side in whole lysosomes and inside-out patches excised from plasma membrane. The PI(3,5)P2-evoked currents were blocked by phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2), but not other phosphoinositides. Using TRPML A487P, which mimics the varitint-waddler (Va) mutant of mouse TRPML3 with constitutive whole-cell currents, we show that TRPML is biphasically regulated by extracytosolic pH, with an optimal pH about 0.6 pH unit higher than that of human TRPML1. In addition to monovalent cations, TRPML exhibits high permeability to Ca(2+), Mn(2+), and Fe(2+), but not Fe(3+). The TRPML currents were inhibited by trivalent cations Fe(3+), La(3+), and Gd(3+). These features resemble more closely to mammalian TRPML1 than TRPML2 and TRPML3, but with some obvious differences. Together, our data support the use of Drosophila for assessing functional significance of TRPML1 in cell physiology.

Dual depolarization responses generated within the same lateral septal neurons by TRPC4-containing channels.

In the central nervous system, canonical transient receptor potential (TRPC) channels have been implicated in mediating neuronal excitation induced by stimulating metabotropic receptors, including group 1 metabotropic glutamate receptors (mGluRs). Lateral septal (LS) neurons express high levels of TRPC4 and group I mGluRs. However, to what extent native TRPC4-containing channels (TRPC4-cc) are activated as well as the impact of different levels of TRPC4-cc activation on neuronal excitability remain elusive. Here, we report that stimulating LS neurons with group I mGluR agonist, (S)-3,5-DHPG, causes either an immediate increase in firing rate or an initial burst followed by a pause of firing, which can be correlated with below-threshold-depolarization (BTD) or above-threshold-plateau-depolarization (ATPD), respectively, in whole-cell recordings. The early phase of BTD and the entire ATPD are completely absent in neurons from TRPC4−/− mice. Moreover, in the same LS neurons, BTD can be converted to ATPD at more depolarized potentials or with a brief current injection, suggesting that BTD and ATPD may represent partial and full activations of TRPC4-cc, respectively. We show that coincident mGluR stimulation and depolarization is required to evoke strong TRPC4-cc current, and Na+ and Ca2+ influx, together with dynamic changes of intracellular Ca(2+), are essential for ATPD induction. Our results suggest that TRPC4-cc integrates metabotropic receptor stimulation with intracellular Ca(2+) signals to generate two interconvertible depolarization responses to affect excitability of LS neurons in distinct fashions.

Bimodal voltage dependence of TRPA1: mutations of a key pore helix residue reveal strong intrinsic voltage-dependent inactivation.

Transient receptor potential A1 (TRPA1) is implicated in somatosensory processing and pathological pain sensation. Although not strictly voltage-gated, ionic currents of TRPA1 typically rectify outwardly, indicating channel activation at depolarized membrane potentials. However, some reports also showed TRPA1 inactivation at high positive potentials, implicating voltage-dependent inactivation. Here we report a conserved leucine residue, L906, in the putative pore helix, which strongly impacts the voltage dependency of TRPA1. Mutation of the leucine to cysteine (L906C) converted the channel from outward to inward rectification independent of divalent cations and irrespective to stimulation by allyl isothiocyanate. The mutant, but not the wild-type channel, displayed exclusively voltage-dependent inactivation at positive potentials. The L906C mutation also exhibited reduced sensitivity to inhibition by TRPA1 blockers, HC030031 and ruthenium red. Further mutagenesis of the leucine to all natural amino acids individually revealed that most substitutions at L906 (15/19) resulted in inward rectification, with exceptions of three amino acids that dramatically reduced channel activity and one, methionine, which mimicked the wild-type channel. Our data are plausibly explained by a bimodal gating model involving both voltage-dependent activation and inactivation of TRPA1. We propose that the key pore helix residue, L906, plays an essential role in responding to the voltage-dependent gating.

Nerve injury inhibits Oprd1 and Cnr1 transcription through REST in primary sensory neurons.

The transcription repressor REST in the dorsal root ganglion (DRG) is upregulated by peripheral nerve injury and promotes the development of chronic pain. However, the genes targeted by REST in neuropathic pain development remain unclear. The expression levels of 4 opioid receptor (Oprm1, Oprd1, Oprl1, Oprk1) and the cannabinoid CB1 receptor (Cnr1) genes in the DRG regulate nociception. In this study, we determined the role of REST in the control of their expression in the DRG induced by spared nerve injury (SNI) in both male and female mice. Transcriptomic analyses of male mouse DRGs followed by quantitative reverse transcription polymerase chain reaction analyses of both male and female mouse DRGs showed that SNI upregulated expression of Rest and downregulated mRNA levels of all 4 opioid receptor and Cnr1 genes, but Oprm1 was upregulated in female mice. Analysis of publicly available bioinformatic data suggested that REST binds to the promoter regions of Oprm1 and Cnr1. Chromatin immunoprecipitation analyses indicated differing levels of REST at these promoters in male and female mice. Full-length Rest conditional knockout in primary sensory neurons reduced SNI-induced pain hypersensitivity and rescued the SNI-induced reduction in the expression of Oprd1 and Cnr1 in the DRG in both male and female mice. Our results suggest that nerve injury represses the transcription of Oprd1 and Cnr1 via REST in primary sensory neurons and that REST is a potential therapeutic target for neuropathic pain.

Brain-derived neurotrophic factor-mediated downregulation of brainstem K+-Cl- cotransporter and cell-type-specific GABA impairment for activation of descending pain facilitation.

Chronic pain is thought to be partly caused by a loss of GABAergic inhibition and resultant neuronal hyperactivation in the central pain-modulating system, but the underlying mechanisms for pain-modulating neurons in the brain are unclear. In this study, we investigated the cellular mechanisms for activation of brainstem descending pain facilitation in rats under persistent pain conditions. In the nucleus raphe magnus (NRM), a critical relay in the brain's descending pain-modulating system, persistent inflammatory pain induced by complete Freund's adjuvant decreased the protein level of K(+)-Cl(-) cotransporter (KCC2) in both total and synaptosomal preparations. Persistent pain also shifted the equilibrium potential of GABAergic inhibitory postsynaptic current (EIPSC) to a more positive level and increased the firing of evoked action potentials selectively in µ-opioid receptor (MOR)-expressing NRM neurons, but not in MOR-lacking NRM neurons. Microinjection of brain-derived neurotrophic factor (BDNF) into the NRM inhibited the KCC2 protein level in the NRM, and both BDNF administration and KCC2 inhibition by furosemide mimicked the pain-induced effects on EIPSC and excitability in MOR-expressing neurons. Furthermore, inhibiting BDNF signaling by NRM infusion of tyrosine receptor kinase B-IgG or blocking KCC2 with furosemide prevented these pain effects in MOR-expressing neurons. These findings demonstrate a cellular mechanism by which the hyperactivity of NRM MOR-expressing neurons, presumably responsible for descending pain facilitation, contributes to pain sensitization through the signaling cascade of BDNF-KCC2-GABA impairment in the development of chronic pain.

Tiam1 coordinates synaptic structural and functional plasticity underpinning the pathophysiology of neuropathic pain.

Neuropathic pain is a common, debilitating chronic pain condition caused by damage or a disease affecting the somatosensory nervous system. Understanding the pathophysiological mechanisms underlying neuropathic pain is critical for developing new therapeutic strategies to treat chronic pain effectively. Tiam1 is a Rac1 guanine nucleotide exchange factor (GEF) that promotes dendritic and synaptic growth during hippocampal development by inducing actin cytoskeletal remodeling. Here, using multiple neuropathic pain animal models, we show that Tiam1 coordinates synaptic structural and functional plasticity in the spinal dorsal horn via actin cytoskeleton reorganization and synaptic NMDAR stabilization and that these actions are essential for the initiation, transition, and maintenance of neuropathic pain. Furthermore, an antisense oligonucleotides (ASO) targeting spinal Tiam1 persistently alleviate neuropathic pain sensitivity. Our findings suggest that Tiam1-coordinated synaptic functional and structural plasticity underlies the pathophysiology of neuropathic pain and that intervention of Tiam1-mediated maladaptive synaptic plasticity has long-lasting consequences in neuropathic pain management.

TIAM1-mediated synaptic plasticity underlies comorbid depression-like and ketamine antidepressant-like actions in chronic pain.

Chronic pain often leads to depression, increasing patient suffering and worsening prognosis. While hyperactivity of the anterior cingulate cortex (ACC) appears to be critically involved, the molecular mechanisms underlying comorbid depressive symptoms in chronic pain remain elusive. T cell lymphoma invasion and metastasis 1 (Tiam1) is a Rac1 guanine nucleotide exchange factor (GEF) that promotes dendrite, spine, and synapse development during brain development. Here, we show that Tiam1 orchestrates synaptic structural and functional plasticity in ACC neurons via actin cytoskeleton reorganization and synaptic N-methyl-d-aspartate receptor (NMDAR) stabilization. This Tiam1-coordinated synaptic plasticity underpins ACC hyperactivity and drives chronic pain-induced depressive-like behaviors. Notably, administration of low-dose ketamine, an NMDAR antagonist emerging as a promising treatment for chronic pain and depression, induces sustained antidepressant-like effects in mouse models of chronic pain by blocking Tiam1-mediated maladaptive synaptic plasticity in ACC neurons. Our results reveal Tiam1 as a critical factor in the pathophysiology of chronic pain-induced depressive-like behaviors and the sustained antidepressant-like effects of ketamine.

Resveratrol noncompetitively inhibits glycine receptor-mediated currents in neurons of rat central auditory neurons.

Resveratrol, a naturally occurring stilbene found in red wine, is known to modulate the activity of several types of ion channels and membrane receptors, including Ca2+, K+, and Na+ ion channels. However, little is known about the effects of resveratrol on some important receptors, such as glycine receptors and GABAA receptors, in the central nervous system (CNS). In the present study, the effects of resveratrol on glycine receptor or GABAA receptor-mediated currents in cultured rat inferior colliculus (IC) and auditory cortex (AC) neurons were studied using whole-cell voltage-clamp recordings. Resveratrol itself did not evoke any currents in IC neurons but it reversibly decreased the amplitude of glycine-induced current (IGly) in a concentration-dependent manner. Resveratrol did not change the reversal potential of IGly but it shifted the concentration-response relationship to the right without changing the Hill coefficient and with decreasing the maximum response of IGly. Interestingly, resveratrol inhibited the amplitude of IGly but not that of GABA-induced current (IGABA) in AC neurons. More importantly, resveratrol inhibited GlyR-mediated but not GABAAR-mediated inhibitory postsynaptic currents in IC neurons using brain slice recordings. Together, these results demonstrate that resveratrol noncompetitively inhibits IGly in auditory neurons by decreasing the affinity of glycine to its receptor. These findings suggest that the native glycine receptors but not GABAA receptors in central neurons are targets of resveratrol during clinical administrations.