Neural mechanism of rebooting the unconsciousness caused by midazolam

LeYuan Gu; WeiHui Shao; Lu Liu; Qing Xu; YuLing Wang; JiaXuan Gu; Yue Yang; ZhuoYue Zhang; YaXuan Wu; Yue Shen; Qian Yu; XiTing Lian; Haixiang Ma; YuanLi Zhang; HongHai Zhang

doi:10.7554/eLife.97954.1

eLife assessment

This study provides a useful set of experiments showing the relative contribution of the Neurodrenergic system in reversing the sedation induced by midazolam. The evidence supporting the claims of the authors is solid, although specificity issues in the pharmacology and neural-circuit investigations narrow down the strengths of the conclusions. After dealing with these limitations, the paper will be of interest to medical biologists working on the neurobiology of anesthesia.

https://doi.org/10.7554/eLife.97954.1.sa2

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solid: Methods, data and analyses broadly support the claims with only minor weaknesses

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Abstract

The advent of midazolam has significant implications for modern clinical practice. The hypnotic and sedative effects of midazolam give it a wide range of clinical utility. However, the specific mechanisms underlying the modulation of altered consciousness by midazolam remain unknown. Herein, using pharmacology, optogenetics, chemogenetics, fiber photometry, and gene knockdown, we revealed the role of locus coeruleus (LC)-ventrolateral preoptic nucleus (VLPO) noradrenergic neural circuit in regulating midazolam-induced altered consciousness. This effect was mediated by α1 adrenergic receptors. Moreover, gamma-aminobutyric acid receptor type A (GABAA-R) is a mechanistically important binding site in the LC for midazolam. Our findings will provide novel insights into the neural circuit mechanisms underlying the recovery of consciousness after midazolam administration and will help guide the timing of clinical dosing and propose effective intervention targets for timely recovery from midazolam-induced loss of consciousness.

Summary

By using pharmacology, optogenetics, chemogenetics, fiber photometry, and gene knockdown, we revealed the role of locus coeruleus (LC)-ventrolateral preoptic nucleus (VLPO) noradrenergic neural circuit in regulating midazolam-induced altered consciousness. This effect was mediated by α1 adrenergic receptors. Moreover, gamma-aminobutyric acid receptor type A (GABAA-R) is a mechanistically important binding site in the LC for midazolam.

Introduction

Midazolam has been widely used in clinical practice for almost fifty years. It is a short-acting benzodiazepine that has a rapid onset and short duration of action and causes relatively mild hemodynamic effects^{1, 2}. It leads to anterograde amnesia and prevents intraoperative awareness and the development of malignant memories in patients. The above characteristics of midazolam make it an indispensable drug for the treatment of psychiatric patients in the United States, China, Europe, and other countries around the world³.

Psychiatric disorders are a common cause of severe and long-term disability and socioeconomic burden worldwide. Insomnia is one of the most prevalent health concerns in the population and clinical practice⁴. The World Health Organization (WHO) reported that about 30% of the adult population worldwide suffer from insomnia, especially alongside other mental and physical health conditions⁵. Intractable insomnia occurs comorbidly with other serious complications such as cognitive and immune decline, emotional disorders, and even suicide^{6, 7}. Oral benzodiazepines, represented by midazolam, are the cornerstone of their therapy regimen⁸. In addition, agitation is a frequent clinical problem seen in a variety of psychiatric disorders that adds significant morbidity to the hospital course⁹. The extensively used medication for patients with acute agitation in the emergency department and intensive care unit is midazolam^{10, 11}. In conclusion, midazolam has become one of the most commonly used psychotropic drugs in clinical practice to induce a sedative response with faded consciousness.

However, a pressing challenge to the application of midazolam in the clinic is the issue of its safety. Depending on the dose, it produces effects ranging from anxiolysis to loss of consciousness, leading it to be versatile to have anxiolytic, sedative and hypnotic effects^{12, 13}. Excessive or long-term use of midazolam often causes increased accumulation and depth of sedation, potentially leading to delayed recovery, which in turn prolongs hospitalization and causes various complications¹⁴. Therefore, it is imperative to explore the mechanisms of midazolam-induced altered consciousness and find promising targets to prevent its complications.

Midazolam has depressant effects on the central nervous system (CNS). It is believed to act on the brainstem reticular formation and limbic system through gamma-aminobutyric acid receptor type A (GABAA-R) to reduce the excitability in the brain, thereby inducing sedation. GABAA-R is the initiating molecular target of midazolam action. However, the specific mechanism of the regulatory systems downstream of the GABAergic system in midazolam-induced altered consciousness remains to be elucidated. Midazolam can induce a similar pattern of electroencephalographic (EEG) to that seen during normal nonrapid eye movement (NREM) sleep, and neither has a sustained long-range specific activation pattern compared to wakefulness¹⁵. Therefore, we postulate that a midazolam-induced loss of consciousness, at least in part, via activation of an endogenous sleep-promoting pathway.

The LC is the primary site for norepinephrine (NE) synthesis and release in the brain and has a wide range of projections to other brain regions¹⁶. The LC^NE neurons, which has been linked to multiple functions, including sleep and arousal, stress-related behaviors, attention, and pain conduction, are reportedly instrumental in sleep–arousal regulation^{17, 18}. Optogenetic activation of LC^NE neurons causes an immediate transition from sleep to wakefulness¹⁹. The ventrolateral preoptic nucleus (VLPO) of the preoptic hypothalamus is recognized as a key “sleep center” in which sleep-activated neurons are responsible for initiating and promoting sleep and are under the control of the LC^NE neurons^20–22. Recently, it has been reported that optogenetic activation of the LC-VLPO NEergic neural circuit promotes arousal from sleep and acts through different adrenergic receptors, indicating the significance of this neural circuit in controlling wakefulness²³. However, natural sleep is a physiological state, whereas drug-induced loss of consciousness is a pathological state, and the two are quite different from a pathophysiological perspective despite some correlation. Furthermore, dexmedetomidine-induced sedation involves the endogenous sleep-promoting pathway of LC-VLPO²⁴. Therefore, these studies offer hints for additional investigation into the role of LC-VLPO NEergic neural circuit in midazolam-induced changes in consciousness. This will enable a more targeted clarification of the neural mechanisms underlying the sedative-hypnotic effects of midazolam, which will have significant clinical implications.

In the present study, it was unveiled that midazolam initially functioned by acting on GABAA-R in the LC. More importantly, we found that the LC-VLPO NEergic neural circuit was instrumental in promoting recovery from midazolam and that this effect was primarily mediated by α1 adrenergic receptors (α1-R). We took a cascading approach from peripheral to central to validate our hypothesis. First, we used pharmacology to investigate the link between the NE system and awakening from midazolam administration. On this basis, we then took more precise and specific approaches, such as optogenetics and chemogenetics to further substantiate our finding and successfully prove the involvement of the NEergic LC-VLPO neural circuit in facilitating the restoration of consciousness after midazolam administration. These results will significantly advance the understanding of the neural circuit mechanisms of midazolam-induced altered consciousness and provide a potential target for intervention in the delayed recovery caused by midazolam.

Results

The noradrenergic system is involved in recovery from midazolam administration

Before starting the following experiments, we first determined the optimal intraperitoneal (IP) dose of midazolam-induced sedation (loss of consciousness). We chose the lowest effective dose that could induce LORR successfully in all of the mice, i.e., 60 mg/kg, as the dose for the subsequent experiments (Figure 1A-B).

To investigate the role of the central noradrenergic system, we individually analyzed the tyrosine hydroxylase (TH) content and activity in the prosencephalon and brainstem of mice (Figure 1C). Since NE in the brain is mainly derived from the brainstem, there were some differences in TH content and activity between the prosencephalon and the brainstem under normal conditions (P<0.05, P<0.001, Figure 1D). However, we also found that compared with the control group, the TH activity in the brainstem was significantly reduced after midazolam administration (P<0.0001, Figure 1D).

Next, we adopted a pharmacological method of peripheral intervention on NE. We found that IP injection of atomoxetine (20 mg/kg), a central selective NE reuptake inhibitor, increased the number of c-Fos (+)/TH (+) cells in the LC (P < 0.01, Figure 1J, L) and shortened the recovery time from midazolam administration (P < 0.05, Figure 1F). Conversely, IP injection of N-(2-chloroethyl)-N-ethyl-2-bromoben-zylamine hydrochloride (DSP-4) (50 mg/kg), a highly selective NEergic neurotoxin, reduced the number of TH+ cells in the LC, most significantly on day 10 after injection (P < 0.0001, Figure 1I, K) and prolonged the recovery time from midazolam administration (P < 0.05, Figure 1G). Moreover, IP injection of DSP-4 for 10 days significantly reversed the recovery-promoting effect of atomoxetine (P < 0.01, Figure 1H). These all data suggest that the noradrenergic system participates in midazolam-induced altered consciousness

The activity of LC^NE neurons is significantly reduced after midazolam administration

Since LC is the largest nucleus in the brain that syntheses and releases NE, we used fiber photometry to measure the neuronal activity of LC^NE neurons at different states after midazolam administration (Figure 2A-B). We injected AAV2/9-DβH-GCaMP6m-WPRE-hGH pA with a specific promoter into the bilateral LC of C57BL/6J mice to express the GCaMP6m calcium indicator specifically in NEergic neurons and examined changes in GCaMP6m fluorescence signal through an optical fiber located in the LC (Figure 2C). We found that during the LORR to RORR phase, the ΔF/F peak of calcium signaling in LC^NE neurons was significantly reduced compared with other phases, and then increased after RORR (P < 0.05, P < 0.01, Figure 2D-G).

LCNE neuronal activity is significantly reduced after midazolam administration and selective ablation of LCNE neurons hinders recovery from midazolam
(A) A schematic of the fiber optic recording of calcium signalings in the LC.
(B) A schematic of the calcium signaling recording device.
(C) A representative photomicrograph showing the microinjection and optical fiber locations and the co-expression of GCaMP6s and TH.
(D) Schematic diagram of the method of dividing the entire recording of the calcium signal at the BLA into four stages, and sources of heatmap and ΔF/F(%) statistical data.
(E) A heatmap of calcium signaling changes in bilateral LCNE neurons induced by midazolam. (Two representative mice were selected for the fiber optic recording of calcium signals, and the whole recording was divided into four stages, each stage as a group for statistical analysis of calcium signaling).
(F) A statistical diagram of calcium signaling changes in bilateral LCNE neurons induced by midazolam.
(G) The peak ΔF/F in the wakefulness, before LORR, LORR-RORR, and after RORR stages.
(H-I) Representative images showing the co-expression of c-Fos and TH in the LC without or with midazolam treatment.
(J) The quantification of c-Fos (+)/TH (+) cells in the LC with midazolam or without midazolam treatment.
(K) Protocol for exploring the influence of intra-LC microinjection DSP-4 on the atomoxetine-mediated shortening of the recovery time from midazolam administration.
(L) The representative photomicrograph shows the tracks of cannulas implanted into bilateral LC.
(M) Results showed the effects of microinjection of DSP-4 (10 days before) into bilateral LC on the recovery time of midazolam.
(N) Results showed the effects of vehicle + vehicle, vehicle + atomoxetine, and DSP-4 (10 days before) + atomoxetine on the recovery time of midazolam.
(O) Comparison of normalized TH (+) cell number in the LC with or without DSP-4 (10 days before) microinjected in the bilateral LC.
(P) Images of TH+ neurons in the LC after microinjection of DSP-4 or vehicle for 10 days (panels on the right show magnified images of the panels on the left).
*p<0.05; **p<0.01; ****p<0.0001

To further evaluate the changes in neuronal activity in the LC after midazolam administration, we performed immunofluorescence staining for c-Fos and TH. Fluorescence images showed a decrease in the number of c-Fos-positive cells co-labeled with TH in the midazolam administration group compared with the control group (P < 0.01, Figure 2H-J). These results indicated that LC^NE neurons were significantly inhibited after midazolam administration.

LC^NE neurons participate in regulating recovery from midazolam

To further explore the role of LC^NE neurons in recovery after midazolam administration, we artificially intervened in LC^NE neurons. We microinjected DSP-4 into LC to specifically degrade LC^NE neurons and found a significant decrease in the number of TH+ neurons in the LC of mice 10 days after the DSP-4 microinjection (P < 0.0001, Figure 2O-P). In addition, microinjection of DSP-4 into the LC significantly prolonged the recovery time and attenuated the recovery-promoting effect of IP-injected atomoxetine in midazolam-induced loss of consciousness (P < 0.05, Figure 2M-N). These suggest that intranuclear administration of DSP-4 to specifically ablate LC^NE neurons suppresses recovery from midazolam administration.

Then, optogenetic manipulation was used to further examine the role of LC^NE neurons (Figure 3A-B). For this purpose, we used a Cre-dependent AAV expressing channelrhodopsin-2 (ChR2) fused with enhanced yellow fluorescent protein (AAV-DIO-ChR2–eYFP) and co-infused it with Cre-AAV expressing the TH promoter (TH-Cre-AAV) to restrict the expression of ChR2 to LC TH+ neurons and an optrode was implanted at the injection site (Figure 3C). We found that photostimulation (20 min/4 mW) of LC^NE neurons significantly shortened the recovery time and produced a pro-recovery effect from midazolam regardless of whether it was left, right, or bilateral LC optogenetic activation (P < 0·05, Figure 3D-F). In addition, fluorescence images showed that c-Fos (+)/TH (+) cells were significantly increased after photostimulation of LC^NE neurons (P < 0.0001, Figure 3G-I).

Optogenetic or chemogentic activation of LCNE neurons promotes recovery from midazolam
(A) Protocol for the effect of photostimulation of LCNE neurons with different light parameters on the recovery time of midazolam.
(B) A schematic of the photogenetic instrument.
(C) A representative photomicrograph showing the locations of optical fiber and virus expression and the co-expression of hChR2 and TH.
(D-E) Results showed the effect of photostimulation of LCNE neurons with different light parameters on the recovery time of midazolam.
(F) Results showed the effect of left, right, and bilateral photostimulation of the LCNE neurons on the recovery time of midazolam.
(G) The quantification of c-Fos (+)/TH (+) cells in the LC with or without photostimulation.
(H-I) Representative images showing the co-expression of c-Fos and TH cells in the LC with or without photostimulation.
(J-K) Protocol and instrument for the effect of chemogenetic activation of LCNE neurons on the recovery time of midazolam.
(L) A representative photomicrograph showing the virus expression and the co-expression of mCherry and TH in the LC of male and female mice.
(M-N) Results showed the effect of chemogenetic activation of LCNE neurons with different doses of CNO (i.p.) on the recovery time of midazolam in male and female mice.
(O-P) Results showed the effect of left, right, and bilateral chemogenetic activation of the LCNE neurons on the recovery time of midazolam in male and female mice.
(Q) Representative images showing the co-expression of c-Fos and TH cells in the LC of male and female mice with or without intraperitoneal injection of CNO (0.2 mg/kg).
(R-S) The quantification of c-Fos (+)/TH (+) cells in the LC with or without chemogenetic stimulation.
PS: photostimulation; CS: chemogenetic stimulation; *p<0.05; ****p<0.0001

Next, we tested whether the chemogenetic activation of LC^NE neurons promotes recovery (Figure 3J). In order to reveal whether there were sex differences in chemogenetic activation of LC^NE neurons, we used both male and female mice, and Cre-dependent excitatory DREADD was co-infused with TH-Cre-AAV to restrict the expression of hM3Dq to LC TH+ neurons (Figure 3K). We determined the transfection efficiency of the chemogenetic virus in LC^NE neurons (Figure 3L). Similar results were obtained in the chemogenetic experiment. We found that in both male and female mice ,IP injection of 0.2 mg/kg CNO could shorten the recovery time and produce a pro-recovery effect from midazolam regardless of whether it was left, right, or bilateral LC chemogenetic activation (P < 0.05, Figure 3M-P). In addition, c-Fos (+)/TH (+) cells were significantly increased after photostimulation of LC^NE neurons (P < 0.0001, Figure 3Q-S). Thus far, we have proven that there were no sex differences in chemogenetic activation of LC^NE neurons, and LC^NE neurons were involved in the recovery from midazolam.

Activation of the LC-VLPO NEergic neural circuit promotes recovery from midazolam

The LC sends projections to several brain regions, including the VLPO, which is a crucial area in regulating sleep and arousal states. Therefore, we hypothesized that LC and VLPO interact to mediate midazolam-induced alterations in consciousness. To verify the existence of the LC–VLPO projection, we microinjected the mix of mTH-Cre-AAV and AAV-EF1a-DIO-hChR2(H134R)-eYFP viruses into the LC and microinjected rAAV2/9-DβH-GCaMP6m-WPRE-hGH pA into the VLPO, and two weeks later implanted optical fibers into the VLPO to record neuronal firing (Figure 4A-C). We observed local NEergic terminals within the VLPO (Figure 4D, H). Also, we found that optogenetic or chemogenetic activation of LCNE neurons led to an enhanced ΔF/F peak in the VLPO (P < 0.05, P < 0.01, Figure 4K-T), i.e., increased VLPO activity, as well as facilitated recovery from midazolam (P < 0.05, Figure 4E, I-J). Moreover, we found that there were no sex differences in chemogenetics studies.

LC-VLPO NEergic neural circuit was involved in the recovery from midazolam
(A) Protocol for optogenetic or chemogenetic activation of LCNE neurons and recording of calcium signaling changes in VLPO.
(B) A schematic of the location of optogenetic or chemogenetic virus injection site in the LC and calcium signaling recording virus injection site in the VLPO.
(C) A representative image showing the co-expression of hChR2 and TH in the LC.
(D) A representative image showing the co-expression of GCaMP6s and TH in the VLPO in male mice.
(E) Results showed the effects of optogenetic activation of LCNE neurons on the recovery time of midazolam.
(F-G) A representative image showing the co-expression of hM3Dq and TH in the LC of male and female mice.
(H) A representative image showing the co-expression of GCaMP6s and TH in the VLPO in female mice.
(I-J) Results showed the effects of chemogenetic activation of LCNE neurons on the recovery time of midazolam in male and female mice.
(K) Schematic diagram of the method of recording the calcium signal at the VLPO, and sources of statistical data.
(L-M) Heatmap and statistical diagram of calcium signaling changes in bilateral VLPO at the after RORR stage with or without optogenetic activation of LCNE neurons. (Showing changes in calcium signaling during the RORR and the Recovery period; optogenetic activation group, n=3; no optogenetic activation group, n=3)
(N) The peak ΔF/F in the VLPO with or without activation of LCNE neurons using optogenetics.
(O-P, R-S) Heatmap and statistical diagram of calcium signaling changes in bilateral VLPO at the after RORR stage with or without chemogenetic activation of LCNE neurons in male and female mice. (Showing changes in calcium signaling during the RORR and the Recovery period; chemogenetic activation group, n=3; no chemogenetic activation group, n=3)
(Q, T) The peak ΔF/F in the VLPO with or without activation of LCNE neurons using chemogenetics in male and female mice.
PS: photostimulation; *p<0.05; **p<0. 01

To further identify whether the LC-VLPO NEergic circuit mediates promoting recovery, we used optogenetics to activate LC^NE terminals in the VLPO. We injected the mixture of mTH-Cre-AAV and AAV-EF1a-DIO-hChR2(H134R)-eYFP viruses into bilateral LC and implanted optical fibers above the VLPO (Figure 5A-B). Immunofluorescence results showed co-expression of hChR2 and TH in axon terminals of VLPO after microinjection of hChR2 in the LC (Figure 5D-E). It confirms the structural association between the LC and the VLPO. In addition, the LC-VLPO NEergic terminals were photostimulated with blue light. We found that the recovery time was shorter in the VLPO photostimulation group than in the no photostimulation group (P < 0.05, Figure 5F). Thus, optogenetic activation of VLPO-projecting LCNE neurons promotes recovery from midazolam.

Activation of LC-VLPO NEergic neural circuit promotes recovery from midazolam
(A) Protocol for intra-LC microinjection of the virus and optogenetic activation of VLPO.
(B-C) Schematic of LC–VLPO long-range optogenetic activation and the location of optogenetic virus microinjection and optic fiber implantation.
(D-E) Representative images showing the co-expression of hChR2 and TH in the LC and VLPO.
(F) Result showed the effect of LC–VLPO long-range optogenetic activation on the recovery time of midazolam.
(G, L) Protocols for exploring the influence of optogenetic or chemogentic activation of NEergic terminals in the VLPO on the recovery time from midazolam.
(H, M) Schematic of the brief process of optogenetic or chemogenetic activation.
(I, N) Schematic of the location of optogenetic or chemogenetic virus microinjection and the location of optic fiber implantation.
(J) A representative photomicrograph showing the co-expression of eYFP and TH in the VLPO.
(K) Results showed the effect of Optogenetic activation of NEergic terminals in the VLPO could reduce the recovery time from midazolam.
(O, Q) A representative photomicrograph showing the co-expression of hM3Dq and TH in the VLPO.
(P, R) Results showed the effect of chemogenetic activation of NEergic terminals in the VLPO could reduce the recovery time from midazolam in both male and female mice.
PS: photostimulation; *p<0.05

Next, in an attempt to further determine the VLPO-projecting NEergic terminals through which the effects described above are exerted, we combined optogenetic or chemogenetic approaches. Besides, we employed both male and female mice in chemogenetic approach to explore whether there were sex differences. We microinjected the AAV optogenetic or chemogenetic viruses expressing the TH promoter into the VLPO, respectively (Figure 5G-H, L-M). We observed the transfection of the viruses in NEergic axon terminals in the VLPO (Figure 9I-J, N-Q). Moreover, we found that compared with the vehicle, optogenetic and chemogenetic activation of NEergic terminals in the VLPO could reduce the recovery time from midazolam, with no sex difference (P < 0.05, Figure 9K, P, R). These suggest that the activation of VLPO-projecting NEergic terminals triggers an immediate pro-recovery effect. Thus far, our results demonstrate the involvement of the LC-VLPO NEergic neural circuit in regulating midazolam-induced altered consciousness.

The promotion of recovery from midazolam is primarily mediated by the α1 adrenergic receptor

To identify the role of different types of noradrenergic receptors in the brain, we used a pharmacological approach. By intracerebroventricular (ICV) injection of different doses of α1-R, α2-R, and β-R agonists and antagonists (Figure 6A), we found that the α1 receptor agonist phenylephrine (20mg/mL) significantly shortened recovery time from midazolam (P < 0.05, Figure 6C). Conversely, the α1 receptor antagonist prazosin (1.5mg/mL), the α2 receptor agonist clonidine (1.5mg/mL), and the β receptor antagonist propranolol (5mg/mL) caused the opposite effects (P < 0.05, Figure 6D, E, H). However, the α2 receptor antagonist yohimbine and the β agonist isoprenaline did not affect the recovery time (P > 0.05, Figure 6F-G), and phenylephrine significantly reversed the effect of propranolol in prolonging recovery time from midazolam (P < 0.01, Figure 6I). These results indicate that the recovery from midazolam is mediated predominantly by α1-R.

ICV injection or intra-VLPO microinjection of α1-R antagonist reverses the pro-recovery effect of optogenetic or chemogenetic of activation LCNE neurons
(A) A schematic of intracerebroventricular injection of different noradrenergic receptor agonists and antagonists.
(B) A representative photomicrograph showing the tracks of cannulas implanted into the lateral ventricle.
(C-H) Results showed the effects of intracerebroventricular injection of different doses of phenylephrine, prazosin, clonidine, yohimbine, isoprenaline, and propranolol on the recovery time of midazolam.
(I) Results showed the effects of intracerebroventricular injection of phenylephrine (20mg/mL) and different doses of propranolol on the recovery time of midazolam.
(J) Protocol for photostimulation of LCNE neurons and intracerebroventricular injection or intra-VLPO microinjection of α1-R antagonist.
(K, L) Schematic of the brief process of optogenetic activation and the representative photomicrograph showing microinjection and optical fiber locations of the co-expression of hChR2 and TH in the LC.
(M, O) A representative photomicrograph showing the tracks of cannulas implanted into the lateral ventricle and bilateral VLPO.
(N, P) Results showed the effects of photostimulation of LCNE neurons and intracerebroventricular injection or intra-VLPO microinjection of prazosin on the recovery time of midazolam.
(Q) Protocol for chemogenetic activation of LCNE neurons and intracerebroventricular injection or intra-VLPO microinjection of an α1-R antagonist.
(R, S) Schematic of the location of virus injection and the representative photomicrograph showing the co-expression of hM3Dq and TH in the LC of male mice.
(T, V) A representative photomicrograph showing the tracks of cannulas implanted into the lateral ventricle and bilateral VLPO in the male mice.
(U, W) Results showed the effects of chemogenetic activation of LCNE neurons and intracerebroventricular injection or intra-VLPO microinjection of prazosin on the recovery time of midazolam in male mice.
(X, Y) A representative photomicrograph showing the co-expression of hM3Dq and TH in the LC and the tracks of cannulas implanted into the bilateral VLPO in the female mice.
(Z) Results showed the effects of chemogenetic activation of LCNE neurons and intra-VLPO microinjection of prazosin on the recovery time of midazolam in female mice.
icv: intracerebroventricular; PS: photostimulation; *p<0.05; **p<0.01; ***p<0.001

The pro-recovery effect of activating LCNE neurons can be reversed by ICV injection or intra-VLPO microinjection of α1-R antagonist

To further determine the link between the LC and VLPO, we assessed the effect of photostimulation and pharmacology (Figure 6J). A mixture of the Cre-dependent AAV vector Ef1a-DIO-hChR2(H134R)-eYFP and mTH-Cre-AAV was injected bilaterally into the LC, and optical fibers were implanted (Figure 6K). 2 weeks later, drug-delivery cannulas were implanted into the ICV or VLPO (Figure 6N, O). Then, we injected prazosin through cannulas within the ICV or VLPO to block α1-R and activate LC by photostimulation to further observe the effects of both on midazolam recovery time. The results showed that photostimulation of LCNE neurons could reduce the recovery time (P < 0.05), whereas prazosin could prolong the recovery time (P < 0.05), and that prazosin reversed the effects produced by LC activation (P < 0.01, P < 0.001, Figure 6N, P). Meanwhile, to further assess the effect of the above maneuvers on the depth of sedation, we performed EEG recordings. We found that light stimulation of the LC resulted in some high-amplitude EEG activity and that the use of prazosin caused inhibitory EEG activity (Figure 7A-C), implying that prazosin or LCNE activation may affect the depth of sedation and produce opposite effects.

Effect of ICV injection of α1-R antagonist and activation of LCNE neurons on EEG activity
(A, D) Schematic diagram of EEG recording method.
(B) EEG and spectrum of mice in vehicle+no PS, vehicle+PS, Prazosin+no PS, and Prazosin+PS at the Before LORR, LORR-RORR, and After RORR stages.
(C) Alpha, Beta, Theta, Gamma, and Delta wave proportion of EEG in four groups of mice in different stages.
(E) EEG and spectrum of mice in vehicle+no CNO, vehicle+ CNO, Prazosin+no CNO, and Prazosin+ CNO at the Before LORR, LORR-RORR, and After RORR stages.
(F) Alpha, Beta, Theta, Gamma, and Delta wave proportion of EEG in four groups of mice in different stages.
PS: photostimulation; *p<0.05; **p<0.01; ***p<0.001

A similar experiment was performed with the chemogenetic approach (Figure 6Q). The mixture of mTH-Cre-AAV and AAV-Ef1a-DIO-hM3Dq-mCherry viruses was injected into bilateral LC (Figure 6R); 2 weeks later, we determined the transfection efficiency of the chemogenetic virus in LCNE neurons in both male and female mice (Figure 6S, X). For male mice, bilateral drug-delivery cannulas were implanted into the ICV or VLPO (Figure 6T, V); For female mice, bilateral drug-delivery cannulas were implanted into the VLPO (Figure 6Y). α1-R antagonist was microinjected through the cannulas and behavioral tests were conducted as well as EEG recordings. Consistent with the above results, in male mice, both ICV and intra-VLPO injections of prazosin prolonged the recovery time (P < 0.01, P < 0.05), and reversed the pro-recovery effect produced by chemogenetic activation of LCNE neurons (P < 0.01, Figure 6U, W). Also, in female mice, intra-VLPO injections of prazosin prolonged the recovery time (P < 0.05), and reversed the pro-recovery effect produced by chemogenetic activation of LCNE neurons (P < 0.001, Figure 6Z). Chemogenetic activation of LC leads to some high-amplitude EEG activity, which could be reversed by prazosin (data from male mice, Figure 7D-F).

In sum, the recovery-promoting effects of all the above-mentioned interventions that can activate LCNE neurons can be reversed by prazosin. We also demonstrated the presence of a functional connection between LCNE neurons and VLPO that co-regulates recovery after midazolam, and α1-R on the VLPO is the downstream target involved in the mechanism of recovery from midazolam.

GABAA-R is an important mechanical binding site for midazolam in the LC

Midazolam is a short-acting central benzodiazepine receptor inhibitor that acts primarily on GABAA-R, thus increasing GABAergic neurotransmission and depressing the CNS. Therefore, we further explored whether LCNE neurons act through GABAA-R after midazolam administration. We microinjected GCaMP6m into the LC in mice and implanted an optical fiber to observe changes in LC calcium signaling after the injection of gabazine, a GABAA receptor antagonist, into the lateral ventricle or LC (Figure 8A). We found that compared with the vehicle, ICV injection and intra-LC microinjection of 4μg/mL gabazine could reduce the recovery time (P < 0.05, Figure 8C, E). In addition, gabazine could increase the ΔF/F peak of calcium signaling in LCNE neurons before LORR and during the RORR to Recovery phase (P < 0.05, Figure 4G-J). These data suggest that GABAA-R in LC may be the initiating binding site of midazolam to produce altered consciousness.

We have already demonstrated that midazolam affects LCNE neuronal activity via GABAA-R in the LC, which then exerts its effects via downstream α1-R. First, drug-delivery cannulas were implanted into the LC and VLPO, respectively. One week later gabazine was injected into the LC to block GABAA-R, while prazosin was injected into the VLPO to antagonize α1-R (Figure 8K-L). We found that microinjection of gabazine into the LC could reduce the recovery time (P < 0.05), whereas microinjection of prazosin into the VLPO could increase the recovery time (P < 0.05, Figure 8N). In addition, we found that microinjection of prazosin into VLPO prolonged the recovery time and significantly reversed the blockade of LC GABAA-R-induced pro-recovery effect (P < 0.05, P < 0.001, Figure 8N).

To investigate the role of GABAA-R on LCNE neurons in the modulation of recovery from midazolam, we performed a loss-of-function study using shRNA to knockdown GABAA-R in the bilateral LCNE neurons. As assessed by immunofluorescence staining analysis, the expression of GABAA-R on LCNE neurons was significantly reduced compared to the sham group (P<0.0001, Figure 9A-F). We found that knockdown of GABAA-R prolonged the recovery time from midazolam, while did not affect the dose of midazolam-induced LORR (P<0.01, Figure 9G-I).

GABA-ergic and NE-ergic systems interact with each other, co-regulate the recovery from midazolam

In previous experiments, we preliminarily proved that GABA-ergic and NE-ergic systems co-regulate recovery from midazolam by the pharmacological method. Then, we combined the gene knockdown technique with fiber photometry to delve deeper (Figure 9J-P). We found that the ΔF/F peak of calcium signaling in the VLPO NE-ergic terminals in the shRNA group was significantly reduced compared with the sham group (P<0.05, Figure 9Q-S).

More importantly, we knocked down GABAA-R on LCNE neurons, resulting in fewer targets for midazolam and weakened function of the GABA-ergic system, and similar to previous results, recovery time from midazolam was reduced. Meanwhile, microinjecting NE α1-R antagonist in the VLPO, we found that the reduction of recovery time caused by the knockdown of GABAA-R was reversed (P<0.05, Figure 9Y), suggesting that the NE-ergic system is indeed involved in recovery from midazolam with NE α1-R on VLPO neurons is an important functional site in the LC-VLPO neural circuit.

Discussion

Midazolam is of great value in the treatment of psychiatric disorders as sedative-hypnotics. Although the number of clinical studies addressing the effects of midazolam on consciousness as well as behavior is slowly increasing, the specific neural mechanisms by which it alters consciousness remain unclear. To fill this gap, we chose midazolam, a clinical drug, to study in mice to find a promising target for the development of an effective strategy to provide targeted therapies for the reversal of midazolam-induced delayed recovery.

In the present study, we cascaded our experiments. First, using pharmacology and ELISA, we verified that the central NE system plays an important role in recovery from midazolam sedation. We found that midazolam administration significantly reduced TH activity in the brainstem and that IP injection of atomoxetine, an NE reuptake inhibitor, could shorten recovery time from midazolam, while peripheral injection of DSP-4 reverses the pro-recovery effect of atomoxetine. Second, based on calcium signaling, we found a decrease in LCNE neuronal activity after midazolam administration. Consistent with this, optogenetic and chemogenetic activation of LCNE neurons could facilitate recovery from midazolam, whereas elective ablation of LCNE neurons by intra-LC microinjection of DSP-4 attenuates recovery. Third, we turned our attention to the downstream pathway of the LC. We found that optogenetic and chemogenetic activation of LCNE neurons could influence the activity of VLPO, and ChR2 can be transmitted from the LC to the VLPO across synapses, suggesting that the LC can project to the VLPO. Next, ICV injection of different adrenergic receptor agonists or antagonists suggested the main involvement of α1-R in the regulative effect of recovery from midazolam. Also, we microinjected α1-R antagonist into VLPO, and we found that the pro-arousal effect induced by activation of LCNE neurons was reversed, suggesting that α1-R in the VLPO is more responsive to regulate recovery from midazolam. Then, ICV injection of the GABAA-R antagonist gabazine or microinjection of gabazine into the LC shortened the recovery time from midazolam, and we found that antagonizing GABAA-R could inhibit the activity of LC, suggesting that GABAA-R in the LC may be an initiating target for the action of midazolam. Finally, by using pharmacological method and gene knockdown technique we found that GABA-ergic and NE-ergic systems co-regulated recovery from midazolam, and GABAA-R on LCNE neurons and NE α1-R on VLPO were the key points. It is worth mentioning that in this study, both male and female mice were used in all chemogenetics experiments, and we found that gender difference did not affect the results of the experiment.

Altered states of consciousness attributed to the action of sedative drugs on molecular targets in the CNS have been the focus of research over the past decades. GABAA-R is a well-recognized target of different sedative agents. GABAA-R is a ligand-gated Cl-channel that mediates the majority of the fast inhibitory neurotransmission in the CNS and has a crucial role in regulating brain excitability. Different GABAA-R subtypes constitute a family of 19 subunit genes, including α1–6, β1–3, γ1–3, δ, ε, θ, π, and ρ1–3, which assemble to form a pentameric structure25. The GABAA-R has a GABA-binding receptor site and some regulatory sites for binding of various substances, and the best characterized regulatory site is the benzodiazepine (BZ) one26. Midazolam is a prevalent psychotropic substance that acts as a positive allosteric modulator of this receptor27. The drug binds highly specifically to the BZ-binding site on the GABAA-R complex, affecting the affinity of GABA and GABA-binding receptor sites and reducing the excitability of the CNS, thus inducing sedation, hypnosis, and unconsciousness. Receptors containing the α1, 2, 3, 5 and γ2 subunit interface form the BZ-binding site of GABAA-R, suggesting the significance of these subunits in midazolam-mediated effects28. It is reported that the duration of the LORR in response to midazolam was reduced in β3-knockout mice compared with wild-type mice, indicating a role of β3-containing GABAA-R in mediating midazolam-induced unconsciousness29. According to our findings, midazolam modulates downstream neural pathways by initially acting on GABAA-R in the LC. It is future studies of membrane proteins and ion channels in LC or non-LC NEergic neurons that we call for to fully understand the molecular and neural circuit targets of sedative-hypnotics.

Midazolam can induce a state of de-consciousness similar to natural sleep. Its effects may engage endogenous sleep-arousal neural nuclei and circuits to induce hypnosis and loss of consciousness. In conjunction with past studies, midazolam and other sedative drugs act primarily by enhancing GABAergic inhibitory neurotransmission, implying a sleep-like facilitating effect of the GABAergic system. However, the mechanism of neural circuits downstream of GABA that regulate changes in consciousness is unclear.

Arousal in the brain depends on many areas that can simultaneously receive different signals, wherein the ascending reticular activating system (ARAS) is responsible for arousal and controls the maintenance of wakefulness30. LCNE neurons, which are an important component of the ARAS, reportedly play a key role in the maintenance of arousal and alertness31. Specifically, we propose that LCNE neurons and their related circuits are involved in modulating recovery from midazolam. In this study, LCNE neurons were activated by photostimulation and chemogenetics to rapidly induce the transition from unconsciousness to awakening. As a key arousal node, the LC receives inputs from arousal-related neurons and provides widespread NEergic innervation to the cerebral cortex and other forebrain structures32. In our study, we first pharmacologically validated the role of the central NEergic system in modulating midazolam recovery, and then, since the LC is the predominant nucleus in the brain for the release of NE, we further demonstrated the role of LCNE neurons in midazolam recovery through selective activation and degradation of them. Here, our study elucidates the critical role of NEergic neurons in the LC in midazolam recovery by pharmacology, optogenetics and chemogenetics.

Next, as the VLPO is downstream of the LC and numerous studies have demonstrated its role in integrating information to promote sleep, we spotlighted the LC-VLPO neural circuit. It has been reported that the VLPO contains multiple neuronal populations, including GABAergic and galaninergic neurons, which are considered to be sleep-active neurons33. Interestingly, there is another cluster of glutamatergic neurons in the VLPO that promote arousal34, 35. A recent report showed that LCNE neurons synergistically promote arousal from sleep by simultaneously activating wake-active neurons and inhibiting sleep-active neurons in the VLPO and the regulation of the two types of neurons in the VLPO is mediated by different adrenergic receptors 23. However, our study is quite different from it. First, our study shows that LC may play an irreplaceable role in midazolam-induced loss of consciousness because atomoxetine is a reuptake inhibitor of widespread NE in the brain, but our selective disruption of LC rendered its effect lost. Second, our study revealed that the GABAA-R in the LC may be the key initiating target for midazolam. Third, we identified this α1 receptor as a necessary target through pharmacology and further validated it with more specific means. Finally, we found that intra-VLPO microinjection of the α1 receptor antagonist prazosin significantly reversed the pro-recovery effect of intra-LC microinjection of GABAA receptor antagonist or activation of LCNE neurons. More importantly, atomoxetine, which is a psychotropic drug commonly used for treating attention-deficit hyperactivity disorder (ADHD), is a promising candidate for translational research to prevent delayed recovery from midazolam abuse in patients with ADHD. Essentially, targeting the central α1-R, particularly in VLPO wake-active neurons, may provide rational therapeutic strategies to prevent delayed recovery. Notably, the VLPO in turn sends GABAergic inhibitory projections to several wake-promoting nuclei throughout the neuroaxis, including the LC36. Several studies have reported that the activated VLPO releases GABA to the LC, thus inducing NREM sleep, and conversely, the NE released from the activated LC inhibits VLPO sleep-active neuron activity and promotes wakefulness37, 38. Therefore, the interactions of the different neuronal populations within the VLPO and their specific connections with the LC in our study need to be further investigated.

The translational implications of a study are a reliable indicator of its impact. The current study has the potential to translate into guidance for the clinical use of midazolam and allow for reducing unwanted drug side effects. On the one hand, we have selected the clinical drug midazolam for animal experiments, which will help us to develop useful drugs to treat midazolam-induced serious complications (e.g., delayed recovery, ventilator-associated pneumonia, and coma) in the future, thus further advancing clinical trials. It provides some hints for management of agitated patients with neuropsychiatric disorders. On the other hand, in addition to intravenous or intramuscular administration, midazolam can also be taken orally to treat insomnia, ameliorate anxiety, and treat seizures and status epilepticus3, 39, 40. Oral midazolam affects consciousness to a greater or lesser extent, and some suicidal patients have even suffered immediate death from massive doses of midazolam. Therefore, our study also provides clues for medication guidance in such patients.

In summary, our study demonstrates that, in mice, the LC-VLPO NEergic neural circuit mediates rapid modulation of altered consciousness induced by midazolam, which is essential to ameliorate the complications of its abuse. It will pinpoint the relevant regions involved in response to midazolam and provide a perspective to help elucidate the dynamic changes of neural circuits in the brain during altered consciousness, as well as suggest a promising new avenue of investigation for the targets of timely recovery from midazolam-induced loss of consciousness, thereby reducing the threat of delayed recovery and its complications.

Limitations

In our study, we indeed verified that the noradrenergic system plays an important role in modulating midazolam recovery. However, in addition to NE, TH is the rate-limiting enzyme for dopamine synthesis, which has been reported to regulate sleep and arousal. Therefore, we cannot totally exclude a modulatory role of the dopaminergic system on midazolam-induced altered consciousness. Second, our method of labeling NE neurons using wild-type mice in conjunction with a virus-mediated exogenous expression strategy was less specific, and to improve the accuracy of our study, the NE-specific mouse strains can be considered in the future. Furthermore, we will employ more specific tracers to track and investigate the neuronal circuit between LC and VLPO as well as the direct synaptic connections from LCNE neurons to VLPO.

Materials and methods

Ethics

This study was approved by and all experimental procedures were performed in compliance with the Experimental Animal Ethics Committee of Zhejiang University.

Animals

The experimental animals in this study were male and female wild-type C57BL/6J mice purchased from the Animal Experiment Center of Zhejiang University. All mice were housed and bred in the SPF-Class House in a standard condition (indoor temperature 25℃, ambient humidity 65%, 12-h/12-h light/dark cycle) with rodent food and water available ad libitum. All mice were aged 8 weeks and weighed 22–25 g at the start of the experiments. All experiments were mainly performed between 9:00 and 16:00.

Establishment of a mice model of midazolam administration

We randomly divided healthy C57BL/6J mice into four groups (n = 8). These mice were used to determine the intraperitoneal dose of midazolam that would achieve the optimal depth without inhibiting respiration before starting the formal experiment. Finally, we identified the lowest effective dose that was 100% successful in inducing loss of consciousness in mice, i.e., 60 mg/kg midazolam (H-19990027, Jiangsu Nhwa Pharmaceutical Co., Ltd.), as the optimal dosage for intraperitoneal administration in mice, and used this dose in subsequent experiments.

Evaluation of recovery time

Before the experiment, the bottom of the open box with no lid and air circulation was covered with cotton pads, and an electric blanket was placed on the lower side of the open box, and the temperature in the open box was preheated for 10 min before the experiment to keep the temperature in the open box suitable and constant during the experiment. Eight-week-old C57BL/6J mice were placed in the open box for 30 min, and then placed in the open box again after intraperitoneal injection of the appropriate dose of midazolam (60 mg/kg) to start the timer. At the same time, the open box was gently rotated every 15 s. When the mice were rotated to the dorsal recumbent position and could not be voluntarily turned over for more than 1 min, it was the loss of righting reflex (LORR), i.e., loss of consciousness from midazolam. Subsequently, the mice were placed in the dorsal recumbent position for continuous observation, and when the mice could autonomously return to the normal position from the dorsal recumbent position, they were considered as recovery of righting reflex (RORR). The time from the onset of LORR to RORR was recorded as the Recovery Time of midazolam.

Enzyme-linked immunosorbent assay (ELISA)

The tyrosine hydroxylase (TH) content and specific enzyme activity were measured in two groups of C57BL/6J mice (n = 6 per group), one group was given 60mg/kg midazolam intraperitoneally and the other group was not. The whole brain was removed and sectioned, and then prosencephalon and brainstem tissue samples were collected separately, and TH levels in these tissues were measured using an enzyme-linked immunosorbent assay (ELISA) kit according to the manufacturer’s instructions (YS-M195, YS-M195-1, ELISA Kit, Yan Sheng Biological Technology Co., Ltd., Shanghai, China). The optical density (OD) was measured at 450 nm and 630 nm using an ELISA microplate reader (SynergyMax M5, iD5, Molecular Devices, San Jose, CA, USA).

Stereotaxic surgery and virus microinjection surgery

Eight-week-old C57BL/6J mice were weighed and injected intraperitoneally with 30 mg/kg of pentobarbital, and placed in the rearing cage for about 5∼10 min. After complete anesthesia, the mice were fixed on a stereotactic apparatus (68018, RWD Life Sciences, Shenzhen, China), and the head hairs of the mice were shaved off with a razor. A heating pad was used to maintain the body temperature of mice at 37°C during the procedure, and an ophthalmic ointment was applied to their eyes to avoid dryness. To expose the skull, the scalp was sterilized and a longitudinal incision was made. The periosteum was then removed with 3% hydrogen peroxide and the residue was rinsed with saline. After drilling holes in the skull, the virus was injected into the target site at a flow rate of 40 nL/min via an ultramicro pump (160494 F10E, WPI). We left the needle at the target site for 10 min after injection to allow for diffusion of the virus. To target the LC, the coordinates were AP: −5.41 mm; ML: ±0.9 mm; DV: −3.8 mm. To target the VLPO, the coordinates were AP: −0.01 mm; ML: ±0.65 mm; DV: −5.7 mm. To target the lateral ventricular, the coordinates were AP: −0.47 mm, ML: −1.00 mm, DV: −2.40 mm. According to the experimental needs, optical fibers or catheters were subsequently implanted in the corresponding location and secured with dental cement. After that, the incision was sutured and the mice were placed on a heating blanket to be transferred to a cage when the mice were awake.

Optogenetics

Three weeks before the experiment began, the LC or VLPO was microinjected with an optogenetic virus of 100 nL of a 1:3 volume mixture of mTH-Cre-AAV and AAV-EF1a-DIO-hChR2(H134R)-eYFP (viral titer: 5.00×1012vg/mL, Brain VTA Technology Co., Ltd., Wuhan, China). One week before the experiment began, the LC or VLPO was implanted with optical fibers (FOC-W-1.25-200-0.37-3.0, Inper, Hangzhou, China). TH-hChR2 expression in the LC and VLPO was determined by immunohistochemistry after the completion of optogenetic experiments. The mice were intraperitoneally injected with midazolam, and 20 min later, they were given 465 nm blue light to activate neurons in the LC or VLPO. In this study, we used different parameters for optogenetic activation: 20 min/2 mW; 20 min/4 mW; 10 min/4 mW; and 20 min/4 mW. We finally identified 20 min/4 mW as the optimal optogenetic activation parameter and used it in the subsequent experiments.

Chemogenetics

Three weeks before starting the experiment, chemogenetic viruses of 100 nL of a 1:3 volume mixture of mTH-Cre-AAV and pAAV-EF1a-DIO-hM3D-mCherry (viral titer: 5.00×1012vg/mL, Brain VTA Technology Co., Ltd., Wuhan, China) were microinjected into the LC or VLPO, and TH-hM3Dq expression in the LC and VLPO was determined by immunohistochemistry after the completion of chemogenetic experiments. Clozapine-N-oxide (CNO) (HY-17366, MedChemExpress) was dissolved in saline, and the mice were intraperitoneally injected with CNO 20 min after intraperitoneally injected with midazolam to activate neurons using the chemogenetics approach. In this study, we tested two concentrations of CNO: 0.1 mg/kg and 0.2 mg/kg. We concluded that 0.2 mg/kg was the optimal concentration and used this concentration for the subsequent intraperitoneal administration.

Fiber photometry

We microinjected 100 nL of rAAV-DβH-GCaMP6m-WPRE-hGH pA (viral titer: 2.00×1012vg/mL, Brain VTA Technology Co., Ltd., Wuhan, China) into the LC or VLPO. Two weeks later, an optical fiber (FOC-W-1.25-200-0.37-3.0, Inper, Hangzhou, China) was implanted in the same area located 0.05 mm above the virus injection point (AP: −5.41 mm; ML: ±0.9 mm; DV: −3.75 mm/AP: −0.01 mm; ML: ±0.65 mm; DV: −5.65 mm) and fixed in place with dental cement. Three weeks after viral expression and one week after fiber optic placement, the calcium activity of the target neurons was monitored. Fluorescence emissions were recorded using a fiber photometry system (Inper, Hangzhou, China, C11946) using a 488-nm diode laser, and the mice were placed in a dark box to avoid the influence of natural light source on calcium signal recording, and accessed to the computer recording software to record calcium signals. After the recording was completed, the results recorded by the optical fiber were read into the calcium signaling data analysis software. The calcium signalings were recorded 30 min before LORR when the mice were awake. Then, midazolam was injected intraperitoneally. After the RORR, the experiment was terminated after 10 min of optical fiber recording. The calcium signal intensity was calculated as the value of ΔF/F=(F-F0)/F0.

GABAA-R Knockdown

We microinjected 80 nL of rAAV-DBH-EGFP-S’miR-30a-shRNA(GABAA receptor)-3’-miR30a-WPRES (viral titer: 5E+12 vg/mL, Brain VTA Technology Co., Ltd., Wuhan, China) into the LC. Four weeks later, these mice were sacrificed and perfused for counting the GABAA-R (+) and tyrosine hydroxylase-positive (TH+) cells to evaluate the effect of GABAA-R knockdown.

Pharmacological experiments

Effects of intraperitoneal injection of atomoxetine and DSP-4 and their interaction on the recovery time of midazolam

Atomoxetine (Ca #Y0001586, Sigma-Aldrich) which selectively inhibits presynaptic uptake of norepinephrine (NE) and enhances norepinephrine function, was dissolved in saline. One hour before intraperitoneal injection with midazolam, C57BL/6J mice received intraperitoneal (IP) injection of atomoxetine (10 mg/kg or 20 mg/kg) or saline (vehicle). To evaluate the impact of peripheral injection of atomoxetine on the recovery time of midazolam, three trials were done for each group of mice (vehicle, 10 mg/kg, and 20 mg/kg), and the recovery time was recorded.

To further verify the effect of norepinephrine on the recovery time of midazolam, we used DSP-4 (C8417, Sigma-Aldrich), a selective neurotoxin that targets the LC norepinephrine system in the rodent brain and is used to disrupt nerve terminals and attenuate NE and NE transporter function in the LC-innervated brain regions. We divided the mice into four groups [vehicle + vehicle, vehicle + atomoxetine, DSP-4 (3 d) + atomoxetine, DSP-4 (10 d) + atomoxetine; n = 6 in each group]. The specific experimental method followed was as follows. C57BL/6J mice received intraperitoneal injection of DSP-4 (50 mg/kg) or saline (vehicle) 3 days before or 10 days before the intraperitoneal injection of atomoxetine (20 mg/kg) or saline (vehicle). One hour later, midazolam was intraperitoneally injected, and the recovery time was recorded. Herein, we verified the physiological effects of DSP-4 using immunohistochemistry.

Effect of intra-LC microinjection of DSP-4 and its interaction with intraperitoneal injection of atomoxetine on the recovery time of midazolam

Ten days before the start of this part of the experiment, cannulas were implanted in bilateral LC of C57BL/6J mice using the same method as mentioned above. DSP-4 (200 nL, 10 µg/µL) or saline (vehicle) was injected into the LC through these guide cannulas. After 10 days, the mice were intraperitoneally administered atomoxetine or saline (vehicle) 1 h before the intraperitoneal injection of midazolam. The recovery time was recorded for vehicle + vehicle, vehicle + atomoxetine, and DSP-4 + atomoxetine groups (n = 6 mice in each group). Using the same protocol as mentioned above, to complete the experiment, the mice were perfused, and their brains were sectioned. Then, the number of TH+ cells in the DSP-4-treated group and vehicle group were counted and compared individually to investigate the effect of DSP-4 microinjection on noradrenergic neurons in bilateral LC.

Effects of lateral ventricle injection and intra-LC microinjection of a GABAA receptor antagonist on the recovery time of midazolam

This experiment was performed in the same batch of 8-week-old C57BL/6J mice 1 week after lateral ventricle cannula and bilateral LC cannula implantation. Three minutes before the intraperitoneal injection of midazolam, 2000 nL of gabazine (2 μg/mL, 4 μg/mL, n = 7, HY-103533, MedChemExpress) was injected into the lateral ventricle cannula or the bilateral cannulas of LC. The recovery time was recorded in each group. During the experiment, the calcium signals were also recorded simultaneously.

Effects of lateral ventricle injection of different adrenoceptor agonists and antagonists on the recovery time of midazolam

The experiment was performed in the same batch of 8-week-old C57BL/6J mice 1 week after lateral ventricle cannula implantation. The mice were administered agonists or antagonists of different adrenergic receptors through the lateral ventricle. Three minutes before intraperitoneal injection of midazolam, 2000 nL of the α1 receptor agonist phenylephrine (10 mg/mL, 20 mg/mL, n = 8, HY-B0471, MedChemExpress) or α1 receptor antagonist prazosin (0.75 mg/mL, 1.5 mg/ml, n = 8, HY-B0193, MedChemExpress) or α2 receptor agonist clonidine (0.75 mg/mL, 1.5 mg/mL, n = 9, HY-B0409, MedChemExpress) or α2 receptor yohimbine (15 μmol/mL, 22.5 μmol/mL, 30 μmol/mL, n = 8, Y111137, Aladdin) or β receptor agonist isoprenaline (2 mg/mL, 4 mg/mL, n = 7, I5627, Sigma-Aldrich) or β receptor antagonist propranolol (2·5 mg/mL, 5 mg/mL, n = 6, HY-B0573, MedChemExpress) or vehicle was administered via the lateral ventricle catheter. The recovery time was recorded.

To further explore the interaction between the α1 receptor and β receptor, we divided the mice into four groups (vehicle + vehicle, phenylephrine, propranolol, and phenylephrine + propranolol). C57BL/6J mice received intracerebroventricular injection of 2000 nL of phenylephrine (20 mg/kg) or propranolol (5 mg/kg) or phenylephrine (20 mg/kg) + propranolol (5 mg/kg) or vehicle, and 3 min later, they were treated with intraperitoneal injection of midazolam. The recovery time was recorded.

Effects of intra-LC microinjection of GABAA receptor antagonist and intra-VLPO microinjection of α1 receptor antagonist on the recovery time of midazolam

To investigate the interaction between GABAergic and noradrenergic systems, we divided the mice into four groups (vehicle + vehicle, gabazine + vehicle, vehicle + prazosin, and gabazine + prazosin). The experiment was performed 1 week after LC or VLPO cannula implantation. 200 nL of Gabazine, prazosin, or vehicle in the same volume was microinjected into the LC or VLPO through the guide cannula. Three minutes later, the mice were intraperitoneally injected with midazolam. The recovery time was recorded.

EEG recording and analysis

Mice with 2 weeks of viral infection in the target brain area were anesthetized with intraperitoneal injection of 30 mg/kg pentobarbital and fixed on a stereotaxic apparatus to expose the skull for leveling. The top of the head was shaved for all mice, and then the skin was sterilized and dissected to expose the skull. Then, four screws with wires were drilled in the left and right of the fontanelle and in the left and right anterior of the posterior fontanelle, and these were then connected to the headstage where the electroencephalogram (EEG) was recorded. This was followed by dental bone cement stabilization and the application of erythromycin ointment to the operative region. Mice equipped with an EEG headstage were housed individually for one week until they adapted to the recording cable and then moved to the experimental barrel, and the EEG activity of the mice was recorded using the EEG monitor and software.

Immunohistochemistry

For immunohistochemistry analysis of the brain, the mice were euthanized after the experiments, and their brains were carefully extracted from the skull. After perfusion with 4% paraformaldehyde (PFA) in phosphate-buffered saline (PBS), the brains were saturated in 30% sucrose for 24 h. Then, coronal slices (thickness, 35 μm) were cut using a freezing microtome (CM30503, Leica Biosystems, Buffalo Grove, IL, USA). Frozen slices were washed three times in PBS for 5 min and incubated in a blocking solution containing 10% normal donkey serum (017-000-121, Jackson Immuno Research, West Grove, PA), 1% bovine serum albumin (A2153, Sigma-Aldrich), and 0·3% Triton X-100 in PBS for 2 h at room temperature. The sections were incubated with primary antibodies at 4℃ overnight; this was followed by incubation in a solution of secondary antibodies for 2 h at room temperature. The primary antibodies used were rabbit anti-TH (1:1000; AB152, Merck-Millipore), mouse anti-TH (1:1000; MAB318, Merck-Millipore), Mouse anti-GABAA-R(1:500; ab94585, Abcam), and rabbit anti-c-Fos (1:1000, 2250T Rabbit mAb, Cell Signaling Technology, Danvers, Massachusetts, USA), and the secondary antibodies used were donkey anti-rabbit Alexa 546 (1:1000; A10040, Thermo Fisher Scientific), donkey anti-mouse Alexa 546 (1:1000; A10036, Thermo Fisher Scientific), Goat anti-rabbit Cy5 (1:1000; A10523, Thermo Fisher Scientific), donkey anti-rabbit Alexa 488 (1:1000; A21206, Thermo Fisher Scientific), and donkey anti-mouse Alexa 488 (1:1000; A21202, Thermo Fisher Scientific). The brain slices were washed three times with PBS for 15 min, and then, they were deposited on glass slides and incubated in a DAPI solution at room temperature for 7 min. Finally, an anti-fluorescence attenuating tablet was applied to seal the slides. Confocal images were acquired using a Nikon A1 laser-scanning confocal microscope (Nikon, Tokyo, Japan), and further image processing was done using ImageJ (NIH, Baltimore, MD).

Statistical analysis

All the experimental data were reported as mean ± SD. GraphPad Prism (GraphPad Software, Inc., San Diego, CA, USA) and SPSS (SPSS Software Inc., Chicago, IL, USA) were used for data visualization and statistical analysis, respectively. Before data analysis, all experimental data were subjected to the Shapiro-Wilk normality test. For comparative analyses of the two groups, if the data were normally distributed, Student’s t-test, including independent samples t-test and paired samples t-test, was used. Conversely, if the data were non-normally distributed, the Mann–Whitney U test or Wilcoxon signed-rank test was used. Notably, the Levene test was used to evaluate the homogeneity of variances. After the data met the normal distribution and homogeneity of variances, a one-way analysis of variance followed by Bonferroni’s multiple comparison test was used for multiple comparisons. P < 0.05 indicated statistical significance.

Author contributions

HHZ designed the study. LYG, WHS, QX and YLW performed and analyzed most of the experiments. LL, JXG, QY and XTL helped with the analysis of experiments. We are grateful to YuDong Zhou and Yi Shen for the experimental design.

Acknowledgements

The work was supported by the National Natural Science Foundation of China (Grant no: 81771403, 81974205), the Natural Science Foundation of Zhejiang Province (LZ20H090001), and the Program of New Century 131 outstanding young talent plan top-level of Hang Zhou to HHZ. We thank YuDong Zhou and Yi Shen for their help in experimental design.

Conflict of interest

The authors declare no conflicts of interest. Data availability

The data supporting the findings of this study are available within the article upon reasonable request.

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Article and author information

Author information

LeYuan Gu
Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, 310006, China, Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
- These authors contributed equally to this work
WeiHui Shao
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
- These authors contributed equally to this work
Lu Liu
Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, 310006, China
- These authors contributed equally to this work
Qing Xu
Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, 310006, China
- These authors contributed equally to this work
YuLing Wang
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
- These authors contributed equally to this work
JiaXuan Gu
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
- These authors contributed equally to this work
Yue Yang
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
ZhuoYue Zhang
Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, 310006, China
YaXuan Wu
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
Yue Shen
Department of Anesthesiology, Affiliated Hangzhou First People’s Hospital, Westlake University School of Medicine, Hangzhou, 310006, China
Qian Yu
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
XiTing Lian
Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, 310006, China
Haixiang Ma
Medical College of Jining Medical University, Ningji, 272067, Shandong, China
YuanLi Zhang
Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China
HongHai Zhang
Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, 310006, China, Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, 310006, China, Department of Anesthesiology, Affiliated Hangzhou First People’s Hospital, Westlake University School of Medicine, Hangzhou, 310006, China, Westlake Laboratory of Life Sciences and Biomedicine, Hangzhou, 310006, China
- Corresponding authors: HongHai Zhang, Email address: zhanghonghai_0902@163.com & zhh0902@zju.edu.cn ORCID: http://orcid.org/0000-0003-3530-2060

Version history

Preprint posted: March 12, 2024
Sent for peer review: March 31, 2024
Reviewed Preprint version 1: May 29, 2024
Reviewed Preprint version 2: October 7, 2024
Version of Record published: November 20, 2024

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

Not revised: This Reviewed Preprint includes the authors’ original preprint (without revision), an eLife assessment, public reviews, and a provisional response from the authors.

Reviewing Editor
Karim Fifel
Mohammed VI Polytechnic University, Ben Guerir, Morocco
Senior Editor
Sacha Nelson
Brandeis University, Waltham, United States of America

Reviewer #1 (Public Review):

In this study, Gu at al., investigated the role of the central noradrenaline system from LC to VLPO in the recovery of consciousness induced by midazolam. Combining pharmacology, optogenetics/chemogenetics, they found that the LC to VLPO NE circuits are essential for consciousness rebooting after midazolam, activation of this circuit strongly speeded up the recovery process, dependent on alpha1 adrenergic receptors in the VLPO neurons. The topic is important and their findings are of some interest.
However, substantial improvements are needed in the language, for grammar, clarity, and layout. There are significant experimental errors (see below 1-2). Further experiments are required to support their main conclusions.

(1) One major issue arises in Figure 4, the recording of VLPO Ca2+ activity. In Lines 211-215, they stated that they injected AAV2/9-DBH-GCaMP6m into the VLPO, while activating LC NE neurons. As they claimed in line 157, DBH is a specific promoter for NE neurons. This implies an attempt to label NE neurons in the VLPO, which is problematic because NE neurons are not present in the VLPO. This raises concerns about their viral infection strategy since Ca activity was observed in their photometry recording. This means that DBH promoter could randomly label some non-NE neurons. Is DBH promoter widely used? The authors should list references. Additionally, they should quantify the labeling efficiency of both DBH and TH-cre throughout the paper.
(2) A similar issue arises with chemogenetic activation in Fig. 5 L-R, the authors used TH-cre and DIO-Gq virus to label VLPO neurons. Were they labelling VLPO NE or DA neurons for recording? The authors have to clarify this.
(3) Another related question pertains to the specificity of LC NE downstream neurons in the VLPO. For example, do they preferentially modulate GABAergic or glutamatergic neurons?
(4) In Figure 1A-D, in the measurement of the dosage-dependent effect of Mida in LORR, were they only performed one batch of testing? If more than one batch of mice were used, error bar should be presented in 1B. Also, the rationale of testing TH expression levels after Mid is not clear. Is TH expression level change related to NE activation specifically? If so, they should cite references.
(5) Regarding the photometry recording of LC NE neurons during the entire process of midazolam injection in Fig. 2 and Fig. 4, it is unclear what time=0 stands for. If I understand correctly, the authors were comparing spontaneous activity during the four phases. Additionally, they only show traces lasting for 20s in Fig. 2F and Fig. 4L. How did the authors select data for analysis, and what criteria were used? The authors should also quantify the average Ca2+ activity and Ca2+ transient frequency during each stage instead of only quantifying Ca2+ peaks. In line 919, the legend for Figure 2D, they stated that it is the signal at the BLA; were they also recorded from the BLA?

https://doi.org/10.7554/eLife.97954.1.sa1

Reviewer #2 (Public Review):

Summary:

This article mainly explores the neural circuit mechanism of recovery of consciousness after midazolam administration and proves that the LC-VLPO NEergic neural circuit helps to promote the recovery of midazolam, and this effect is mainly caused by α1 adrenergic receptors. (α1-R) mediated.

Strengths:

This article uses innovative methods such as optogenetics and fiber optic photometry in the experimental methods section to make the stimulation of neuronal cells more precise and the stimulation intensity more accurate in experimental research. In addition, fiber optic photometry adds confidence to the results of calcium detection in mouse neuronal cells.

This article explains the results from the entire system down to cells, and then cells gradually unfold to explain the entire mechanism. The entire explanation process is logical and orderly. At the same time, this article conducted a large number of rescue experiments, which greatly increased the credibility of the experimental conclusions.

Throughout the full text and all conclusions, this article has elucidated the neural circuit mechanism of recovery of consciousness after midazolam administration and successfully verified that the LC-VLPO NEergic neural circuit helps promote the recovery of midazolam.

The conclusions of this article are crucial to ameliorate the complications of its abuse. It will pinpoint relevant regions involved in midazolam response and provide a perspective to help elucidate the dynamic changes in neural circuits in the brain during altered consciousness and suggest a promising approach towards the goal of timely recovery from midazolam. New research avenues.

At the same time, this article also has important clinical translation significance. The application of clinical drug midazolam and animal experiments have certain guiding significance for subsequent related clinical research.

https://doi.org/10.7554/eLife.97954.1.sa0

Author Response:

We sincerely value the insightful and constructive feedback provided by the reviewers, which has been instrumental in identifying areas of our manuscript that required further clarification or amendment. Below are our responses detailing each comment.

Reviewer 1:

(1) One major issue arises in Figure 4, the recording of VLPO Ca2+ activity. In Lines 211-215, they stated that they injected AAV2/9-DBH-GCaMP6m into the VLPO, while activating LC NE neurons. As they claimed in line 157, DBH is a specific promoter for NE neurons. This implies an attempt to label NE neurons in the VLPO, which is problematic because NE neurons are not present in the VLPO. This raises concerns about their viral infection strategy since Ca activity was observed in their photometry recording. This means that DBH promoter could randomly label some non-NE neurons. Is DBH promoter widely used? The authors should list references. Additionally, they should quantify the labeling efficiency of both DBH and TH-cre throughout the paper.

(1) In Figure 5, we found that the VLPO received the noradrenergic projection from LC, indicating the recorded Ca2+ activity may come from the axon fibers corresponding to the projection. Similarly, Gunaydin et al. (2014) demonstrated that fiber photometry can be used to selectively record from neuronal projection.

(2) Located in the inner membrane of noradrenergic and adrenergic neurons, DBH (Dopamine-beta-hydroxylase) is an enzyme that catalyzes the conversion of dopamine to norepinephrine, and therefore plays an important role in noradrenergic neurotransmission. DBH is a marker of noradrenergic neurons. Zhou et al. (2020) clarified the probe specifically labeled noradrenergic neurons by immunolabeling for DBH. Recently, DBH promoter have been used in several studies (e.g., Han et al., 2024; Lian et al., 2023). The DBH-Cre mice are widely used to specifically labeled noradrenergic neurons (e.g., Li et al., 2023; Breton-Provencher et al., 2022; Liu et al., 2024). As reviewer said, it is difficult to distinguish the role of NE or DA neurons when using the TH promoter in VLPO. Therefore, we used DBH promoter with more specific labeling. LC is the main noradrenergic nucleus of the central nervous system. In our study, we injected rAAV-DBH-GCaMP6m-WPRE (Figure 2 and 8) and rAAV-DBH-EGFP-S'miR-30a-shRNA GABAA receptor)-3’-miR30a-WPRES (Figure 9) into the LC. The results showed that DBH promoter could specifically label noradrenergic neurons in the LC, while non-specific markers outside the LC were almost absent. As suggested, we will quantify the labeling efficiency of both DBH and TH-cre throughout the revised manuscript. This updated figure will provide a more rigorous analysis.

(2) A similar issue arises with chemogenetic activation in Fig. 5 L-R, the authors used TH-cre and DIO-Gq virus to label VLPO neurons. Were they labelling VLPO NE or DA neurons for recording? The authors have to clarify this.

As previously addressed in response to Comment #1, we acknowledge that it is difficult to distinguish the role of NE or DA neurons when using the TH promoter in VLPO. In the revised manuscript, we are considering conducting more restricted AAV injections into the VLPO to verify terminal expressions in the LC.

(3) Another related question pertains to the specificity of LC NE downstream neurons in the VLPO. For example, do they preferentially modulate GABAergic or glutamatergic neurons?

As suggested, we will supplement the multi-label ISH of LC NE downstream neurons in the VLPO to reveal the types of neurons they modulate.

(4) In Figure 1A-D, in the measurement of the dosage-dependent effect of Mida in LORR, were they only performed one batch of testing? If more than one batch of mice were used, error bar should be presented in 1B. Also, the rationale of testing TH expression levels after Mid is not clear. Is TH expression level change related to NE activation specifically? If so, they should cite references.

(1) As recommended, we will supplement error bar in the revised manuscript.

(2) As reviewer suggested, the use of TH as a marker of NE activation is controversial, so in the revised manuscript, we will directly determine central norepinephrine content.

(5) Regarding the photometry recording of LC NE neurons during the entire process of midazolam injection in Fig. 2 and Fig. 4, it is unclear what time=0 stands for. If I understand correctly, the authors were comparing spontaneous activity during the four phases. Additionally, they only show traces lasting for 20s in Fig. 2F and Fig. 4L. How did the authors select data for analysis, and what criteria were used? The authors should also quantify the average Ca2+ activity and Ca2+ transient frequency during each stage instead of only quantifying Ca2+ peaks. In line 919, the legend for Figure 2D, they stated that it is the signal at the BLA; were they also recorded from the BLA?

(1) In this study, we used optical fiber calcium signal recording, which is a fluorescence imaging based on changes in calcium. The fluorescence signal is usually divided into different segments according to the behavior, and the corresponding segments are orderly according to the specific behavior event as the time=0. The mean calcium fluorescence signal in the time window 1.5s or 1s before the event behavior is taken as the baseline fluorescence intensity (F0), and the difference between the fluorescence intensity of the occurrence of the behavior and the baseline fluorescence intensity is divided by the difference between the baseline fluorescence intensity and the offset value. That is, the value ΔF/F0 represents the change of calcium fluorescence intensity when the event occurs. The results of the analysis are commonly represented by two kinds of graphs, namely heat map and event-related peri-event plot (e.g., Cheng et al., 2022; Gan-Or et al., 2023; Wei et al., 2018). In Fig. 2, the time points for awake, midazolam injection, LORR and RORR in mice were respectively selected as time=0, while in Fig. 4, RORR in mice was selected as time=0. The selected traces lasting for 20s was based on the length of a complete Ca2+ signal. We will explain the Ca2+ recording experiment more specifically in the revised manuscript.

(2) To the BLA, we sincerely apologize for our carelessness, the signal we recorded were from the LC rather than the BLA. We will carefully check and correct similar problems in the revised manuscript.

Reviewer 2:

In figure legends, abbreviations in figure should be supplemented as much as possible. For example, "LORR" in Figure 1.

As suggested, we will supplement abbreviations in figure as much as possible in the revised manuscript.

References

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Zhou N, Huo F, Yue Y, Yin C. Specific Fluorescent Probe Based on "Protect-Deprotect" To Visualize the Norepinephrine Signaling Pathway and Drug Intervention Tracers. J Am Chem Soc. 2020;142(41):17751-17755. doi:10.1021/jacs.0c08956

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https://doi.org/10.7554/eLife.97954.1.sa3

Significance of findings

Strength of evidence

Abstract

Summary

Introduction

Results

The noradrenergic system is involved in recovery from midazolam administration

The activity of LCNE neurons is significantly reduced after midazolam administration

LCNE neurons participate in regulating recovery from midazolam

Activation of the LC-VLPO NEergic neural circuit promotes recovery from midazolam

The promotion of recovery from midazolam is primarily mediated by the α1 adrenergic receptor

The pro-recovery effect of activating LCNE neurons can be reversed by ICV injection or intra-VLPO microinjection of α1-R antagonist

GABAA-R is an important mechanical binding site for midazolam in the LC

GABA-ergic and NE-ergic systems interact with each other, co-regulate the recovery from midazolam

Discussion

Limitations

Materials and methods

Ethics

Animals

Establishment of a mice model of midazolam administration

Evaluation of recovery time

Enzyme-linked immunosorbent assay (ELISA)

Stereotaxic surgery and virus microinjection surgery

Optogenetics

Chemogenetics

Fiber photometry

GABAA-R Knockdown

Pharmacological experiments

Effect of intra-LC microinjection of DSP-4 and its interaction with intraperitoneal injection of atomoxetine on the recovery time of midazolam

Effects of lateral ventricle injection and intra-LC microinjection of a GABAA receptor antagonist on the recovery time of midazolam

Effects of lateral ventricle injection of different adrenoceptor agonists and antagonists on the recovery time of midazolam

Effects of intra-LC microinjection of GABAA receptor antagonist and intra-VLPO microinjection of α1 receptor antagonist on the recovery time of midazolam

EEG recording and analysis

Immunohistochemistry

Statistical analysis

Author contributions

Acknowledgements

Conflict of interest

References

Article and author information

Author information

LeYuan Gu#

WeiHui Shao#

Lu Liu#

Qing Xu#

YuLing Wang#

JiaXuan Gu#

Yue Yang

ZhuoYue Zhang

YaXuan Wu

Yue Shen

Qian Yu

XiTing Lian

Haixiang Ma

YuanLi Zhang

HongHai Zhang

Version history

Copyright

Peer review process

Editors

The activity of LC^NE neurons is significantly reduced after midazolam administration

LC^NE neurons participate in regulating recovery from midazolam

LeYuan Gu

WeiHui Shao

Lu Liu

Qing Xu

YuLing Wang

JiaXuan Gu