Electromagnetic Navigation Bronchoscopy for Peripheral Pulmonary Lesions: One-Year Results of the Prospective, Multicenter NAVIGATE Study
Medtronic. Dr. Nead has received personal fees from Medtronic. Dr. Bowling has received personal fees from Medtronic. Dr. Murgu has received personal fees from Medtronic, Boston Scientific, Pinnacle Biologics, Olympus, Cook, Auris Robotics, and Elsevier; and has stock ownership in Concordia, Boston Scientific, and Merck. Dr. Krimsky has received personal fees from Medtronic, Innovital Systems, Gala Therapeutic, SOC, and Peytant; has stock ownership with Innovital Systems and CSA Medical; and has patents pending with Medtronic and Merit. Dr. Murillo has received support from Medtronic. Dr. LeMense has received personal fees from Medtronic. Dr. Minnich has received personal fees from Medtronic. Dr. Bansal has received personal fees from Medtronic, Pinnacle Biologics, Sunovion, and Veran Medical. Dr. Ellis has received support from Medtronic. Dr. Mahajan has received personal fees from Medtronic. Dr. Gildea has received personal fees from Medtronic. Dr. Bechara has received support from Medtronic. Dr. Sztejman has received support from Medtronic. Dr. Flandes has received grants from BTG-PneumRx and Ambu; and personal fees from Medtronic, BTG-PneumRx, Olympus, Ambu, PulmonX, and Boston Scientific. Dr. Rickman has received personal fees from Medtronic, Veran Medical, BD, Olympus, and Abbvie. Dr. Benzaquen has received support from Medtronic. Dr. Hogarth has received personal fees from Medtronic, Auris Surgical Robotics, Boston Scientific, Grifols, Shire, and CSL; and has stock ownership with Auris Surgical Robotics. Dr. Linden has received support from Medtronic. Dr. Wahidi has received personal fees from Medtronic and Veran Medical. Dr. Mattingley has received personal fees from Medtronic and is current employee of Medtronic (employment began after completion of enrollment). Dr. Hood is an employee with stock ownership at Medtronic; and has stock ownership with Boston Scientific. Ms. Lin and Ms. Wolvers are employees with stock ownership at Medtronic. Dr. Khandar has received personal fees from Medtronic.
BackgroundThe Robotic Endoscopic System (Auris Health, Inc., Redwood City, CA) has the potential to overcome several limitations of contemporary guided-bronchoscopic technologies for the diagnosis of lung lesions. Our objective is to report on the initial post-marketing feasibility, safety and diagnostic yield of this technology.MethodsWe retrospectively reviewed data on consecutive cases in which robot-assisted bronchoscopy was used to sample lung lesions at four centers in the US (academic and community) from June 15th, 2018 to December 15th, 2018.ResultsOne hundred and sixty-seven lesions in 165 patients were included in the analysis, with an average follow-up of 185 ± 55 days. The average size of target lesions was 25.0 ± 15.0 mm. Seventy-one percent were located in the peripheral third of the lung. Pneumothorax and airway bleeding occurred in 3.6 and 2.4% cases, respectively. Navigation was successful in 88.6% of cases. Tissue samples were successfully obtained in 98.8%. The diagnostic yield estimates ranged from 69.1 to 77% assuming the cases of biopsy-proven inflammation without any follow-up information (N = 13) were non-diagnostic and diagnostic, respectively. The yield was 81.5, 71.7 and 26.9% for concentric, eccentric and absent r-EBUS views, respectively. Diagnostic yield was not affected by lesion size, density, lobar location or centrality.ConclusionsRAB implementation in community and academic centers is safe and feasible, with an initial diagnostic yield of 69.1–77% in patients with lung lesions that require diagnostic bronchoscopy. Comparative trials with the existing bronchoscopic technologies are needed to determine cost-effectiveness of this technology.
TRPC6 channel translocation into phagosomal membrane augments phagosomal function
Defects in the innate immune system in the lung with attendant bacterial infections contribute to lung tissue damage, respiratory insufficiency, and ultimately death in the pathogenesis of cystic fibrosis (CF). Professional phagocytes, including alveolar macrophages (AMs), have specialized pathways that ensure efficient killing of pathogens in phagosomes. Phagosomal acidification facilitates the optimal functioning of degradative enzymes, ultimately contributing to bacterial killing. Generation of low organellar pH is primarily driven by the V-ATPases, proton pumps that use cytoplasmic ATP to load H+ into the organelle. Critical to phagosomal acidification are various channels derived from the plasma membrane, including the anion channel cystic fibrosis transmembrane conductance regulator, which shunt the transmembrane potential generated by movement of protons. Here we show that the transient receptor potential canonical-6 (TRPC6) calcium-permeable channel in the AM also functions to shunt the transmembrane potential generated by proton pumping and is capable of restoring microbicidal function to compromised AMs in CF and enhancement of function in non-CF cells. TRPC6 channel activity is enhanced via translocation to the cell surface (and then ultimately to the phagosome during phagocytosis) in response to G-protein signaling activated by the small molecule (R)-roscovitine and its derivatives. These data show that enhancing vesicular insertion of the TRPC6 channel to the plasma membrane may represent a general mechanism for restoring phagosome activity in conditions, where it is lost or impaired.
Dual role of PKA in phenotypic modulation of vascular smooth muscle cells by extracellular ATP
Extracellular ATP is released from activated platelets and endothelial cells and stimulates proliferation of vascular smooth muscle cells (VSMC). We found that ATP stimulates a profound but transient activation of protein kinase A (PKA) via purinergic P2Y receptors. The specific inhibition of PKA by adenovirus-mediated transduction of the PKA inhibitor (PKI) attenuates VSMC proliferation in response to ATP, suggesting a positive role for transient PKA activation in VSMC proliferation. By contrast, isoproterenol and forskolin, which stimulate a more sustained PKA activation, inhibit VSMC growth as expected. On the other hand, the activity of serum response factor (SRF) and the SRF-dependent expression of smooth muscle (SM) genes, such as SM-alpha-actin and SM22, are extremely sensitive to regulation by PKA, and even transient PKA activation by ATP is sufficient for their downregulation. Analysis of the dose responses of PKA activation, VSMC proliferation, SRF activity, and SM gene expression to ATP, with or without PKI overexpression, suggests the following model for the phenotypic modulation of VSMC by ATP, in which the transient PKA activation plays a critical role. At low micromolar doses, ATP elicits a negligible effect on DNA synthesis but induces profound SRF activity and SM gene expression, thus promoting the contractile VSMC phenotype. At high micromolar doses, ATP inhibits SRF activity and SM gene expression and promotes VSMC growth in a manner dependent on transient PKA activation. Transformation of VSMC by high doses of ATP can be prevented and even reversed by inhibition of PKA activity.
Regulation of Serum Response Factor-Dependent Gene Expression by Proteasome Inhibitors
Serum response factor (SRF) is activated by contractile and hypertrophic agonists, such as endothelin-1 (ET1) to stimulate expression of cytoskeletal proteins in vascular smooth muscle cells (VSMCs). While studying the regulation of smooth muscle ␣-actin (SMA) expression at the level of protein stability, we discovered that inhibition of proteasome-dependent protein degradation by N-benzoyloxycarbonyl (Z)-Leu-Leu-leucinal (MG132) or lactacystin (LC) did not enhance the levels of SMA, but, unexpectedly, attenuated SMA expression in response to ET1, without affecting the viability of VSMCs. Down-regulation of SMA protein by MG132 or LC occurred at the level of SMA transcription and via the inhibition of SRF activity. By contrast, MG132 and LC potentiated the activity of activator protein-1 transcription factor. Regulation of SRF by MG132 was not related to inhibition of nuclear factor-B, an established target of proteasome inhibitors, and was not mediated by protein kinase A, a powerful regulator of SRF activity. Signaling studies indicate that inhibition of ET1-induced SRF activity by MG132 occurs at the level downstream of heterotrimeric G proteins Gq/11 and G13, of small GTPase RhoA, and of actin dynamics but at the level of SRF-DNA binding. MG132 treatment did not result in ubiquitination or accumulation of SRF. By contrast, the levels of c-Jun were rapidly increased upon incubation of cells with MG132, and ectopic overexpression of c-Jun mimicked the effect of MG132 on SRF activity. Together, these data suggest that inhibition of proteasome results in down-regulation of SMA expression via up-regulation of c-Jun and repression of SRF activity at the level of DNA binding.
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