Breathing Rats Research Articles

Inhalation of the Novel Tryptophan Hydroxylase 1 Inhibitor TPT-004 Alleviates Pulmonary Arterial Hypertension.

Inhaled pharmacotherapies are promising treatment options for patients with pulmonary arterial hypertension (PAH) as they minimize extrapulmonary adverse effects. Recently, we developed a highly specific inhibitor (TPHi) of the serotonin synthesizing enzyme tryptophan hydroxylase 1, TPT-004. We hypothesized that repetitive nose-only inhalation of TPT-004 alleviates PAH and pulmonary vascular remodeling in the Sugen-hypoxia (SuHx) rat model. Male Sprague-Dawley rats were divided into 3 groups: (i) ConNx, control animals kept in room air during the study; (ii) SuHx [rats subcutaneously injected with the VEGFR2-inhibitor SU5416, then exposed to chronic hypoxia (3 weeks), followed by 5.5 weeks of room air]; (iii) SuHx + TPHi [SuHx animals treated with TPHi by inhalation for 4 weeks]. Closed-chest right-left heart catheterization and cardiac MRI were performed in spontaneously breathing rats. Lungs underwent histological and mRNA-seq analysis. SuHx-exposed rats had severe PAH, RV hypertrophy, and RV dilation. In comparison with SuHx-exposed rats, TPHi-treated SuHx rats had significantly lower RV systolic pressure (67.25 vs.51.47mmHg; p<0.0001), normalized RV end-systolic volume (182.6 vs. 105.1µL; p<0.0001) and improved RV ejection fraction by cardiac MRI (47.9 vs. 66.8%; p<0.0001). Inhaled TPT-004 did not affect LV end-diastolic or systemic blood pressure. TPT-004 therapy reversed pulmonary vascular remodeling and alveolar macrophage infiltration. RNA-sequencing unraveled TPHi-induced changes in pulmonary gene expression: 1) increased cell adhesion and reduced cell motility/migration; 2) suppressed extracellular matrix remodeling; 3) modulated immune response; 4) suppressed pulmonary vascular remodeling via modulating proliferation, apoptosis, and homeostasis. Taken together, TPT-004 is an effective therapeutic PAH agent, does not cause any hemodynamic adverse effects in rodents, and thus, should be tested further towards a clinical phase 1b/phase 2 study in PAH patients.

Intravenous bolus injection of fentanyl triggers an immediate central and upper airway obstructive apnea via activating vagal sensory afferents.

Intravenous bolus (IVb) injection of fentanyl induces an immediate apnea, but the characteristics of the apnea and relevant mechanism remain unclear. Here, we tested whether IVb injection of fentanyl induced an immediate central and upper airway obstructive apnea associated with chest wall rigidity via activating vagal C-fibers (VCFs) and vagal afferent opioid receptors (ORs). Cardiorespiratory and electromyography of external and internal intercostal, thyroarytenoid, and superior pharyngeal constrictor muscles (EMGEI, EMGII, EMGTA, and EMGSPC) responses to IVb injection of fentanyl were recorded in anesthetized and spontaneously breathing rats with or without bilateral perivagal capsaicin treatment or intravagal microinjection of naloxone. An immunohistochemical approach was employed to define the presence of opioid mu-receptor (MOR) expression in vagal C-neurons, and a patch clamp technique was utilized to determine the evoked current responses of vagal C-neurons to fentanyl in vitro. Fentanyl induced an immediate apnea and subsequent respiratory depression. The apnea was characterized by cessation of EMGEI activity and augmentation of tonic discharges of EMGII, EMGTA, and EMGSPC, i.e., central expiratory apnea, laryngeal closure, and pharyngeal constriction/collapse accompanied with chest wall rigidity. The apneic response was abolished by blockade of VCF signal conduction and largely attenuated by antagonism of vagal afferent ORs. The latter significantly alleviated the initial (within 5-min postinjection), but not the latter, respiratory depression. Vagal C-neurons expressed MORs and were activated by fentanyl. We conclude that IVb injection of fentanyl causes a VCF- and vagal afferent OR-mediated immediate central apnea, upper airway obstruction, and chest wall rigidity.NEW & NOTEWORTHY Intravenous bolus injection of fentanyl triggers an immediate apnea, but the nature of apnea and relevant mechanisms remain unknown. Results in this study reveal that this fentanyl injection concurrently triggers an immediate central and upper airway obstructive apnea associated with chest wall rigidity via activating vagal sensory C-fibers.

Extended oxygen supplementation after thoracotomy in rats may improve welfare.

A retrospective comparison of welfare indicators in male rats undergoing thoracotomy for intrapleural dosing is presented. The initial cohort (n = 7) breathed room air after recovery from anaesthesia, while later cohorts (n = 12) had oxygen supplementation for up to 48 h post-surgery. Rats breathing room air sustained a statistically significant average body-weight loss of -1.62% (±1.7%) 2 days after surgery, compared with rats given oxygen supplementation, which maintained a mean weight gain of 0.87% (±1.75%) (p = 0.009). Oxygen-supplemented rats also had lower pain scores on the evening after surgery (median 0.075 [range 0-1.75] vs. median 1.5 [range 0.5-2]). This difference was not statistically significant (p = 0.063) but may be of clinical significance. All rats displayed transient sedation after post-operative opioid administration on the day of surgery, and hypoxaemia (SpO2 <90%) was observed in rats maintained on room air. Use of an oxygen concentrator to provide post-operative extended oxygen supplementation was easy to implement and may improve animal welfare post-thoracotomy.

Differential impact of chronic intermittent hypoxia and stress changes on condylar development

ObjectivesThis study aimed to determine the effects of chronic intermittent hypoxia (CIH) and stress change (SC) on the development of the condyle in mouth breathing rats. DesignA total of 120 4-week-old rats were randomly assigned to one of five groups. The control (Ctrl) group was the blank control and the intermittent nasal obstruction (INO) group was the positive control. Mild CIH (mCIH) and severe CIH (sCIH) groups were developed by adjusting environmental oxygen concentration and monitoring real-time blood oxygen saturation (SpO2). The SC group was developed using INO, increased environmental oxygen concentration, and real-time SpO2 monitoring. Six rats from each group were sacrificed for analysis at 0, 1, 2, or 4 weeks. ResultsSimilar to the INO group, condyle and mandibular body development in the sCIH group, but not in the mCIH group, was significantly inhibited compared with the Ctrl group. The SC group had inhibited development of the condyle, especially of the posterior zone, but had minimal impact on the growth of the mandible. ConclusionThe inhibitory effects of CIH on the development of the condyle and mandibular body were SpO2-dose-dependent. When SC occurred, inhibited development was observed in the posterior zone of condyle but not the whole mandible. These findings provide important insights for targeted interventions that address the consequences of mouth breathing in children.

Cardiorespiratory failure induced by inhalation of aerosolized fentanyl in anesthetized rats

Intravenous rapid injection of fentanyl causes respiratory depression (severe apneas), leading to sudden death, which constitutes the deadliest drug reaction among overdoses of synthetic opioids. Here we asked whether acute inhalation of overdose fentanyl would also result in similar respiratory failure and death. The anesthetized and spontaneously breathing rats with tracheal cannulation were exposed to aerosolized fentanyl at 100 mg/m3 (FNTH) or 30 mg/m3 (FNTL) for 10 min. Minute ventilation (VE), electromyography (EMG) of the internal and external intercostal muscles and thyroarytenoid muscles (EMGII, EMGEI, and EMGTA), heart rate and arterial blood pressure were recorded. During the exposure, FNTH and FNTL immediately triggered bradypnea (40 % reduction, p < 0.05) with TE prolonged and then gradually decreased VE by 40 % (P < 0.05) after a brief VE recovery. The initial TE prolongation (apneas) were characterized by the cessation of EMGEI activity with enhanced tonic discharges of EMGTA and EMGII. After termination of the exposure, the cardiorespiratory responses to FNTL returned to the baseline values 30 min later, while those to FNTH were greatly exacerbated (P < 0.05), leading to ventilatory and cardiac arrest occurred 16.4 ± 4.7 min and 19.3 ± 4.5 min respectively after the onset of FNTH. The ventilatory arrest was featured by cessation of both EMGEI and EMGII and augmentation of tonic EMGTA. Our results suggest that acute exposure to an overdose of fentanyl aerosol leads to death through initially inducing a brief central and upper airway obstructive apnea as well as chest wall rigidity followed by gradual severe hypoventilation, bradycardia and hypotension, and eventual cardiorespiratory arrest in anesthetized rats.

Tropine exacerbates the ventilatory depressant actions of fentanyl in freely-moving rats.

Our lab is investigating the efficacy profiles of tropine analogs against opioid-induced respiratory depression. The companion manuscript reports that the cell-permeant tropeine, tropine ester (Ibutropin), produces a rapid and sustained reversal of the deleterious actions of fentanyl on breathing, alveolar-arterial (A-a) gradient (i.e., index of alveolar gas exchange), and arterial blood-gas (ABG) chemistry in freely-moving male Sprague Dawley rats, while not compromising fentanyl analgesia. We report here that in contrast to Ibutropin, the injection of the parent molecule, tropine (200μmol/kg, IV), worsens the adverse actions of fentanyl (75μg/kg, IV) on ventilatory parameters (e.g., frequency of breathing, tidal volume, minute ventilation, peak inspiratory and expiratory flows, and inspiratory and expiratory drives), A-a gradient, ABG chemistry (e.g., pH, pCO2, pO2, and sO2), and sedation (i.e., the righting reflex), while not affecting fentanyl antinociception (i.e., the tail-flick latency) in freely-moving male Sprague Dawley rats. These data suggest that tropine augments opioid receptor-induced signaling events that mediate the actions of fentanyl on breathing and alveolar gas exchange. The opposite effects of Ibutropin and tropine may result from the ability of Ibutropin to readily enter peripheral and central cells. Of direct relevance is that tropine, resulting from the hydrolysis of Ibutropin, would combat the Ibutropin-induced reversal of the adverse effects of fentanyl. Because numerous drug classes, such as cocaine, atropine, and neuromuscular blocking drugs contain a tropine moiety, it is possible that their hydrolysis to tropine has unexpected/unintended consequences. Indeed, others have found that tropine exerts the same behavioral profile as cocaine upon central administration. Together, these data add valuable information about the pharmacological properties of tropine.

Assessing Functional Recovery of Eupneic Diaphragm Activity Following Unilateral Cervical Spinal Cord Injury in Rats.

Following cSCI, activation of the DIAm can be impacted depending on the extent of the injury. The present manuscript describes a unilateral C2 hemisection (C2SH) model of cSCI that disrupts eupneic ipsilateral diaphragm (iDIAm) electromyographic (EMG) activity during breathing in rats. To evaluate recovery of DIAm motor control, the extent of deficit due to C2SH must first be clearly established. By verifying a complete initial loss of iDIAm EMG during breathing, subsequent recovery can be classified as either absent or present, and the extent of recovery can be estimated using the EMG amplitude. Additionally, by measuring the continued absence of iDIAm EMG activity during breathing after the acute spinal shock period following C2SH, the success of the initial C2SH may be validated. Measuring contralateral diaphragm (cDIAm) EMG activity can provide information about the compensatory effects of C2SH, which also reflects neuroplasticity. Moreover, DIAm EMG recordings from awake animals can provide vital physiological information about the motor control of the DIAm after C2SH. This article describes a method for a rigorous, reproducible, and reliable C2SH model of cSCI in rats, which is an excellent platform for studying respiratory neuroplasticity, compensatory cDIAm activity, and therapeutic strategies and pharmaceuticals.

Dexamethasone weakens the respiratory effects of pro-inflammatory cytokine TNF-α in rat

The goal of the current study was to identify the role of the glucocorticoids in the respiratory effects of proinflammatory cytokines. For this purpose intravenous injections of TNF-α were used in anesthetized spontaneously breathing rats before and after pretreatment of dexamethasone, a synthetic steroid with predominant glucocorticoid activity. Dexamethasone was injected intraperitoneally at a dose of 1 mg/kg. TNF-α was administrated into the tail vein at a dose of 40 mg/kg. We found that dexamethasone pretreatment eliminated the cytokine-induced increase in pulmonary ventilation and decrease in the hypoxic ventilatory response. Dexamethasone had a pronounced rapid effect on the respiratory activity of TNF-α as early as 30 minutes after administration. Therefore, we assume that this mechanism of action of dexamethasone was non-genomic, associated with the blocking of secondary mediators of the cytokine response.

TNF-a Receptor 1 Activity Is Differentially Required for Phrenic Long-term Facilitation (pLTF) Over the Course of Motor Neuron Death in Adult Rats

Intrapleural injection of cholera toxin B fragment conjugated to saporin (CTB-SAP) selectively kills respiratory motor neurons, and mimics aspects of neuromuscular disorders and neurodegenerative diseases including phrenic motor neuron death, decreased phrenic motor output, and increased microglial cell number. Over the course of motor neuron loss, enhanced A2A receptor-dependent phrenic plasticity is observed early (7d), and then constrained 5-HT receptor-dependent phrenic plasticity is observed later (28d). In addition, COX-1/2-induced inflammation differentially impacts breathing and phrenic plasticity in CTB-SAP rats, but the underlying mechanism by which COX-1/2-induced inflammation impacts breathing and plasticity over the course of motor neuron death has not been studied. We observe that increased cervical neuroinflammatory gene expression ( e.g., tumor necrosis factor-a; TNF-a) is reduced back to control levels in the presence of ketoprofen in CTB-SAP rats, and it is known that TNF-a is involved in phrenic plasticity in naïve rats. Thus, we hypothesized that acute TNF-a receptor inhibition attenuates phrenic plasticity at 7d and enhances it at 28d TNF-a following CTB-SAP-induced neuropathology. Using anesthetized, paralyzed and ventilated CTB-SAP-treated adult Sprague Dawley rats, we studied acute intermittent hypoxia (AIH; 3, 5 min bouts of 10.5% O2) induced pLTF following acute intrathecal C4 delivery of a TNF-a receptor 1 inhibitor (soluble TNFR1; sTNFR1; 0.13 ug/ul) or vehicle (aCSF) to rats that received bilateral, intrapleural injections of: 1) CTB-SAP (25ug), or 2) un-conjugated CTB and SAP (control) in rats treated 7d or 28d prior. Surprisingly, preliminary results indicate that acute sTNFR1 delivery does not affect pLTF in 7d CTB-SAP-treated rats (n=5; i.e., pLTF still enhanced) but it enhanced pLTF in 28d CTB-SAP-treated rats (n=6; p&lt;0.05) vs. controls (n=6 at 7d; n=7 at 28d) and vs. vehicle treated rats (controls n=6 for 7d and n=9 for 28d; CTB-SAP, n=4 for 7d and 28d each). These preliminary observations suggest that TNF-a does not contribute to pLTF in 7d CTB-SAP-treated rats, whereas it may undermine pLTF in 28d CTB-SAP-treated rats. Studies are underway to assess the cellular source of TNF-a and the impact of chronic sTNFR1 delivery on pLTF, diaphragm activity, and breathing. Since most patients with neuromuscular disorders or neurodegenerative disease develop respiratory insuffciency and ultimately become ventilator dependent, our long-range goal is to develop new strategies to enhance the functional capacity of spared motor neurons and reduce ventilatory compromise in motor neuron loss pathology. These novel strategies, if successful, will identify new therapeutic targets for future, translational studies to enhance breathing in patients with neuromuscular disorders. Supported by a Spinal Cord Injury and Disease Research grant. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Spinal TNF-α receptor expression in a rodent model of respiratory motor neuron death

Intrapleural injection of cholera toxin B fragment conjugated to saporin (CTB-SAP) selectively kills respiratory motor neurons, and mimics aspects of neurodegenerative diseases including breathing deficits. In this model, phrenic long-term facilitation (pLTF) induced by acute intermittent hypoxia is enhanced following 7 days (d) of CTB-SAP vs. control rats, whereas pLTF in 28d CTB-SAP treated rats is comparable to pLTF in controls suggesting that the underlying mechanisms of plasticity at both time points differ. Inflammation is a hallmark of neurodegenerative diseases and is known to prevent pLTF. Furthermore, ketoprofen (NSAID) delivery attenuates pLTF in 7d CTB-SAP-treated rats, but enhances it in 28d CTB-SAP-treated rats; this suggests that inflammation contributes to pLTF in 7d CTB-SAP-treated rats, but undermines pLTF in 28d CTB-SAP-treated rats. In addition, cervical spinal inflammatory marker gene expression ( e.g., TNF-a) is increased in CTB-SAP rats, and pilot data suggest that soluble TNF receptor 1 (sTNFR1) inhibition differentially affects pLTF (Nichols and Smith , ibid). Thus, the goal of the current study is to investigate TNFR1 as a pharmacological target that can modulate inflammation to maximize pLTF and breathing in CTB-SAP rats. We hypothesized that C4 TNFR1 expression would be increased on phrenic motor neurons and glial cells of CTB-SAP rats vs. controls. To address this, we studied TNFR1 expression on phrenic motor neurons and glial cells using immunohistochemistry, confocal microscopy, and ImageJ analysis in male Sprague Dawley rats 7 and 28 days after intrapleural injection of: CTB-SAP or un-conjugated CTB and SAP (control); n=8/group. Our preliminary data (n=4/group) suggest that phrenic TNFR1 expression is increased in 7d CTB-SAP rats vs. controls (p&lt;0.05), but is unaffected in 28d CTB-SAP rats vs. controls (p&gt;0.05). Further data analysis is underway for phrenic as well as glial TNFR1 expression in CTB-SAP rats vs. controls. If C4 TNFR1 expression is increased, this would suggest that TNFR1 is a viable target for therapeutic intervention in CTB-SAP rats, and potentially in patients with breathing deficits due to respiratory motor neuron death. NSF Computational Neuroscience grant, MU CVM COR grant, and Spinal Cord Injury &amp; Disease Research Program grant. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Chronic Hyperoxia Augments the Hypercapnic Ventilatory Response in Adult Rats

Rats exposed to 4 – 14 days of 60% O2 as adults exhibit a modest enhancement of their hypoxic ventilatory response (HVR) (Danielson &amp; Bavis, Physiology 38(S1): 5730119, 2023). To determine whether this plasticity is unique to the HVR or a general increase in excitability of the respiratory control system, we tested the hypothesis that chronic hyperoxia would also enhance the hypercapnic ventilatory response (HCVR). The ventilatory response to 7% CO2 was measured by whole-body plethysmography in adult, Sprague-Dawley rats immediately after 4 and 14 days of exposure to 60% O2 or an equivalent time period in room air. Baseline ventilation and the HCVR were unchanged after 4 days of hyperoxia. The HCVR was increased after 14 days (Treatment × FICO2, P=0.004), with hypercapnic ventilation being approximately 15% greater than in control rats. However, this effect was no longer significant after accounting for variation in metabolic rate, and the HCVR was fully recovered when rats were restudied four weeks after they were returned to room air. In a follow-up experiment, pulse oximetry was performed in isoflurane-anesthetized rats breathing room air or 12% O2. Exposure to 4 – 14 days of 60% O2 did not impair gas exchange, so augmented ventilatory responses likely reflect changes in the neural control of breathing and/or metabolism rather than differences in the levels of hypoxemia and hypercapnia experienced by rats during the tests. In conclusion, chronic hyperoxia elicits plasticity in both the HVR and HCVR of adult rats, but these responses recover in less than one month after rats are returned to room air. Supported by NIH grant P20 GM-103423 (Maine INBRE). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Low Doses of Kretek Cigarette Smoke Altered Rat Lung Histometric, and Overexpression of the p53 Gene.

The components of kretek cigarettes include tobacco as the main part, clove, and sauce. Filtered kretek cigarettes are kretek cigarettes that have one end filtered. Cigarette smoke contributes to the disruption of the respiratory system, so it is necessary to know the effect of low doses of cigarette smoke on changes in the histometric of the respiratory system, and whether it affects p53 gene expression. This study aims to determine changes in the histometric of the respiratory system and p53 gene expression. In this study, we used Sprague-Dawley rats. Group I of rats breathing normal air, were not exposed to filtered kretek cigarette smoke (as a control). Group II of rats, as a treatment group, were exposed to filtered kretek cigarette smoke 1 stick/day for 3 months. The results of lung histometry measurements and p53 gene expression between groups were analyzed using the Independent Sample T-test. The difference between groups is significant if the test results show P < 0.05. Bronchioles length, width, area, and perimeter in group I were 40.55±1.57 μm, 14.82±0.41 μm, 494.61±5.62 μm2, and 233.87±4.51 μm, respectively. Bronchioles length, width, area, and perimeter in group II were 30.76±0.78 μm, 9.28±0.40 μm, 297.32±2.53 μm2, and 177.84±5.15 μm, respectively. The area and perimeter of respiratory bronchioles in group I were 17.68±0.49 μm2, and 26.60±0.52 μm respectively, while those in group II were 19.28±0.35 μm2, and 29.28±0.35 μm, respectively. Mucus was found in the bronchioles and respiratory bronchioles in group II, however, there was no visible mucus observed in group I. In addition, it was also concluded that exposure to low doses of filtered kretek cigarette smoke, 1 cigarette/day for 3 months, increased the expression of the p53 gene in the lungs of rats. The size of bronchioles in rats decreased after being exposed to filtered kretek cigarette smoke 1 stick/day for 3 months, while the size of respiratory bronchioles increased. In addition, exposure to filtered kretek cigarette smoke increased the expression of the p53 gene in the rat lungs.

Stimulatory effect of methylglyoxal on capsaicin-sensitive lung vagal afferents in rats: role of TRPA1.

Methylglyoxal (MG), a reactive metabolic byproduct of glycolysis, is a causative of painful diabetic neuropathy. Patients with diabetes are associated with more frequent severe asthma exacerbation. Stimulation of capsaicin-sensitive lung vagal (CSLV) afferents may contribute to the pathogenesis of hyperreactive airway diseases such as asthma. However, the possibility of the stimulatory effect of MG on CSLV afferents and the underlying mechanisms remain unknown. Our results showed that intravenous injection of MG (25 mg/kg, MG25) in anesthetized, spontaneously breathing rats elicited pulmonary chemoreflexes characterized by apnea, bradycardia, and hypotension. The MG-induced apneic response was reproducible and dose dependent. MG25 no longer evoked these reflex responses after perineural capsaicin treatment of both cervical vagi to block C-fibers' conduction, suggesting that the reflexes were mediated through the stimulation of CSLV afferents. Pretreatment with HC030031 [an antagonist of transient receptor potential ankyrin subtype 1 protein (TRPA1)] or AP18 (another TRPA1 antagonist), but not their vehicle, markedly attenuated the apneic response induced by MG25. Consistently, electrophysiological results showed that pretreatment with HC030031 largely attenuated the intense discharge in CSLV afferents induced by injection of MG25 in open-chest and artificially ventilated rats. In isolated CSLV neurons, the perfusion of MG evoked an abrupt and pronounced increase in calcium transients in a concentration-dependent manner. This stimulatory effect on CSLV neurons was also abolished by HC030031 treatment but not by its vehicle. In conclusion, these results suggest that MG exerts a stimulatory effect on CSLV afferents, inducing pulmonary chemoreflexes, and such stimulation is mediated through the TRPA1 activation.NEW & NOTEWORTHY Methylglyoxal (MG) is implicated in the development of painful diabetic neuropathy. A retrospective cohort study revealed an increased incidence of asthma exacerbations in patients with diabetes. This study demonstrated that elevated circulating MG levels stimulate capsaicin-sensitive lung vagal afferents via activation of TRPA1, which in turn triggers respiratory reflexes. These findings provide new information for understanding the pathogenic mechanism of diabetes-associated hyperreactive airway diseases and potential therapy.

Comparison of the μ-Opioid Receptor Antagonists Methocinnamox and Naloxone to Reverse and Prevent the Ventilatory Depressant Effects of Fentanyl, Carfentanil, 3-Methylfentanyl, and Heroin in Male Rats.

The number of opioid overdose deaths has increased significantly over the past decade. The life-threatening effect of opioids is hypoventilation, which can be reversed by the μ-opioid receptor (MOR) antagonist naloxone; however, because of the very short duration of action of naloxone, reemergence of MOR agonist-induced hypoventilation can occur, requiring additional doses of naloxone. The MOR antagonist methocinnamox (MCAM) antagonizes hypoventilation by the nonmorphinan fentanyl and the morphinan heroin in laboratory animals with an unusually long duration of action. Whole-body plethysmography was used to compare the potency and effectiveness of MCAM and naloxone for preventing and reversing hypoventilation by fentanyl, heroin, and the ultrapotent and longer-acting fentanyl analogs carfentanil and 3-methylfentanyl in male rats breathing normal air. Sessions comprised a 45-minute habituation period followed by intravenous administration of saline or an acute dose of MOR agonist. The rank order of potency to decrease ventilation was 3-methylfentanyl > carfentanil > fentanyl > heroin. MCAM (0.0001-0.1 mg/kg) and naloxone (0.0001-0.01 mg/kg) dose dependently reversed hypoventilation by 3-methylfentanyl (0.01 mg/kg), carfentanil (0.01 mg/kg), fentanyl (0.1 mg/kg), or heroin (3.2 mg/kg). For prevention studies, MCAM, naloxone, or vehicle was administered intravenously 22, 46, or 70 hours prior to a MOR agonist. When administered 22 hours earlier, MCAM (0.1-1.0 mg/kg) but not naloxone (1.0 mg/kg) prevented hypoventilation by each MOR agonist. This study demonstrates the effectiveness of MCAM at reversing and preventing hypoventilation by MOR agonists including ultrapotent fentanyl analogs that have a long duration of action. SIGNIFICANCE STATEMENT: The number of opioid overdose deaths increased over the past decade despite the availability of antagonists that can prevent and reverse the effects of opioids. This study demonstrates the effectiveness and long duration of action of the μ-opioid receptor (MOR) antagonist methocinnamox (MCAM) for reversing and preventing hypoventilation by MOR agonists including ultrapotent fentanyl analogs. These results provide support for the notion that MCAM has the potential to positively impact the ongoing opioid crisis by reversing and preventing opioid overdose.

Brainstem astrocytes regulate breathing and may affect arousal state in rats

Variations in arousal levels can impact respiratory patterns. The mechanisms by which breathing behaviors can influence arousal state is not fully understood. In this study, we investigated the role of astrocytes in the preBötzinger complex (preBötC) in modulating arousal states via breathing in adult conscious rats. Using viral vector tools, we selectively interfered with astrocytic signaling in the preBötC. Rats with inhibited astrocytic signaling exhibited slower breathing rates and behaviors indicative of a calmer state, whereas enhanced purinergic signaling in preBötC astrocytes led to faster breathing and heightened arousal. Our findings reveal a key role for an astrocyte-mediated mechanism in the preBötC that influences both respiratory behaviors and higher-order brain functions like arousal, suggesting a bidirectional link between breathing behaviors and mental states.

Hyperventilation worsens inflammatory lung injury in spontaneously breathing rats.

Here, we investigated the effects of hyperventilation on acute lung injury (ALI) in spontaneously breathing rats. Wistar rats were randomized to receive either intraperitoneal lipopolysaccharides (LPS) or saline, and intravenous infusion of NH4Cl (to induce metabolic acidosis and hyperventilation) or saline. Four groups were established: control-control (C-C), control-hyperventilation (C-HV), LPS-control (LPS-C), and LPS-hyperventilation (LPS-HV). Venous blood gases were collected before and after NH4Cl infusion and analyzed to confirm the presence of metabolic acidosis and hyperventilation. After euthanasia, lung injury was assessed using the ALI score, morphometric quantification of perivascular edema, neutrophil counts in the bronchoalveolar lavage, and mRNA expression of biological markers in the lung tissue. Hyperventilation induced inflammatory lung injury in previously healthy lungs and exacerbated injuries previously induced by LPS (ALI score: C-C=0.14 [IQR 0.12; 0.14]; C-HV=0.36 [IQR 0.31; 0.37]; LPS-C=0.51 [IQR 0.50; 0.54]; LPS-HV=0.58 [IQR 0.56; 0.62]; p<0.01). Perivascular edema, neutrophil counts in bronchoalveolar lavage, and amphiregulin mRNA expression were higher in the LPS-HV group compared to the control group. Hyperventilation increased inflammatory injury in rats with ALI during spontaneous ventilation. These results suggest that the impact of vigorous spontaneous breathing efforts on worsening inflammatory lung injury warrants further investigation.

Acute Hyperoxia Improves Spinal Cord Oxygenation and Circulatory Function Following Cervical Spinal Cord Injury in Rats.

Spinal cord injury is associated with spinal vascular disruptions that result in spinal ischemia and tissue hypoxia. This study evaluated the therapeutic efficacy of normobaric hyperoxia on spinal cord oxygenation and circulatory function at the acute stage of cervical spinal cord injury. Adult male Sprague Dawley rats underwent dorsal cervical laminectomy or cervical spinal cord contusion. At 1-2 days after spinal surgery, spinal cord oxygenation was monitored in anesthetized and spontaneously breathing rats through optical recording of oxygen sensor foils placed on the cervical spinal cord and pulse oximetry. The arterial blood pressure, heart rate, blood gases, and peripheral oxyhemoglobin saturation were also measured under hyperoxic (50% O2) and normoxic (21% O2) conditions. The results showed that contused animals had significantly lower spinal cord oxygenation levels than uninjured animals during normoxia. Peripheral oxyhemoglobin saturation, arterial oxygen partial pressure, and mean arterial blood pressure are significantly reduced following cervical spinal cord contusion. Notably, spinal oxygenation of contused rats could be improved to a level comparable to uninjured animals under hyperoxia. Furthermore, acute hyperoxia elevated blood pressure, arterial oxygen partial pressure, and peripheral oxyhemoglobin saturation. These results suggest that normobaric hyperoxia can significantly improve spinal cord oxygenation and circulatory function in the acute phase after cervical spinal cord injury. We propose that adjuvant normobaric hyperoxia combined with other hemodynamic optimization strategies may prevent secondary damage after spinal cord injury and improve functional recovery.

Respiratory sinus arrhythmia in spontaneously breathing, unanesthetized newborn and adult Wistar rats

We examined respiratory sinus arrhythmia (RSA) and possible interaction with respiratory frequency (fR) and heart rate (HR) in spontaneously breathing, unanesthetized newborn Wistar rats (2- to 5-day-old; n = 54) and the adult rats (8-week-old; n = 34). Instantaneous heart rate (inst-HR) was calculated as the reciprocal of the inter-beat-interval. For each breath, RSA was determined as the difference between the maximum and minimum inst-HR value. The absolute RSA or RSA% (RSA per HR) were calculated as the average RSA of 10 consecutive breaths. RSA (or RSA%) in the newborn rats was significantly lower than that in the adult rats. Correlation coefficient between RSA (or RSA%) and 1/fR or HR/fR, but not HR, was significant in newborn rats, whereas only that between RSA (or RSA%) and HR was significant in adult rats. The power spectrum density of heartbeat fluctuation was detectable in both age groups. The present findings suggest that RSA exists and could be influenced by fR, rather than HR, in newborn rats.

Abstract 179: Reversal of Clinical Death by Intra-Arterial Infusion of Phospholipid Nanoparticles (VBI-1)

Introduction: Ninety percent of deaths from potentially survivable injuries on the battlefield are attributed to hemorrhagic shock, leading to clinical death (CD) with the loss of pulse and respiratory drive before reaching a surgeon. However, currently available fluids are inadequate for rescuing warfighters who have experienced exsanguination. Furthermore, these fluids have the potential to cause reperfusion injury in vital organs. We developed a rat model of CD to evaluate the effectiveness of two phospholipid nanoparticle formulations (VBI-1, VBI-S) and compared intra-arterial (IA) versus intravenous (IV) infusion on resuscitation. Hypothesis: We hypothesized that the nanoparticles would restore breathing and blood pressure (BP) in rats after CD induced by hemorrhagic shock. Goals: To establish a model that reliably restores breathing and maintains a survivable BP for 240 minutes after CD. Methods: Male and female Sprague Dawley rats were divided into four groups (n=6-7). The rats were anesthetized with isoflurane, followed by cannulation of femoral arteries. Blood was withdrawn over two minutes until respiration ceased. Equal volumes of either Ringer’s Lactate (LR), shed blood, VBI-1, or VBI-S were infused over one minute, with continuous monitoring of BP. Results: Loss of respiration occurred with blood withdrawal ranging from 39.8% to 43.2% of the predicted total blood volume. Post-IA infusion, the survival rates of the four groups for 240 minutes were as follows: 100% with VBI-1 (n=6), 83.3% with blood (n=7), 66.7% with VBI-S (n=6), and 0% with LR (n=6). Two-way ANOVA analysis revealed a significant difference in mean arterial pressure (MAP) among the four fluids (p=0.0004). Post-hoc analysis indicated the fluid responsiveness in elevating MAP as follows: VBI-1 &gt; VBI-S = shed blood &gt; LR. Regarding the VBI-1 infusion routes, the IA infusion demonstrated 100% survival (n=6) compared to the IV infusion with 40% (n=6) survival. Conclusion: VBI-1 outperformed all other fluids, including blood, in achieving reanimation and elevating MAP. IA infusion of VBI-1 demonstrated a higher reanimation rate compared to IV infusion. Based on these findings, VBI-1 is a promising new treatment for CD due to severe hemorrhagic shock; potentially saving lives.

Neuromotor control of spontaneous quiet breathing in awake rats evaluated by assessments of diaphragm EMG stationarity.

The neuromotor control of the diaphragm muscle (DIAm) is dynamic. The activity of the DIAm can be recorded via electromyography (EMG), which represents the temporal summation of motor unit action potentials. Our goal in the present study was to investigate DIAm neuromotor control during quiet spontaneous breathing (eupnea) in awake rats by evaluating DIAm EMG at specific temporal locations defined by motor unit recruitment and derecruitment. We evaluated the nonstationarity of DIAm EMG activity to identify DIAm motor unit recruitment and derecruitment durations. Combined with assessments of root mean square (RMS) and sum of squares (SS) EMG, the durations of these phases provide physiological information about the temporal aspects of motor control. During eupnea in awake rats (n = 10), the duration of motor unit recruitment comprised 61 ± 19 ms of the onset-to-peak duration (214 ± 62 ms) of the DIAm RMS EMG. The peak-to-offset duration of DIAm EMG activity was 453 ± 96 ms, with a terminating period of derecruitment of 161 ± 44 ms. The burst duration was 673 ± 128 ms. Both the RMS EMG amplitude and the SS EMG were higher at the completion of motor unit recruitment than at the start of motor unit derecruitment, suggesting that offset discharge rates were lower than onset discharge rates. Our analyses provide novel insights into the time domain aspects of DIAm neuromotor control and allow indirect estimates of the contribution of recruitment and frequency to RMS EMG amplitude during eupnea in awake rats.NEW & NOTEWORTHY We characterized three phases of neuromotor control-motor unit recruitment, sustained activity, and derecruitment-based on statistical assessments of stationarity of the diaphragm muscle (DIAm) EMG activity in awake rats. Our findings may allow indirect estimates of the contribution of motor unit recruitment and frequency coding toward generating force and provide novel insights about the temporal aspects of DIAm neuromotor control and descending respiratory drive in unanesthetized animals.