Midazolam has been extensively utilized in clinical practice for nearly half a century. This benzodiazepine exhibits rapid onset and a short duration of action, and causes relatively mild hemodynamic effects (Mandrioli et al., 2008; Reves et al., 1985). It induces anterograde amnesia, thereby averting intraoperative awareness and mitigating the emergence 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 numerous other countries worldwide (Conway et al., 2016).

Psychiatric disorders globally constitute a significant source of severe, long-term disability and socioeconomic strain. Among these,insomnia stands as a prevalent health issue in the general population and clinical settings (Perlis et al., 2022). The World Health Organization reported that about 30% of the adult population worldwide suffer from insomnia, especially alongside other mental and physical health conditions (Sutton, 2021). Intractable insomnia frequently co-occurs with severe complications, including cognitive and immune decline, emotional disorders, and suicidal tendencies (Buysse, 2013; Gebara et al., 2018). Oral benzodiazepines, exemplified by midazolam, constitute the foundation of their therapy regimen (Riemann et al., 2015). Furthermore, agitation, a prevalent clinical issue in numerous psychiatric disorders, significantly compounds morbidity during hospitalization (Citrome, 2021). The extensively used medication for patients with acute agitation in the emergency department and intensive care unit is midazolam (Kim et al., 2021; Shafer, 1998). In conclusion, midazolam has emerged as one of the most commonly administered psychotropic drugs in clinical practice, effectively inducing a sedative response with diminished consciousness.

However, a critical challenge in the clinical application of midazolam pertains to its safety profile. 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 (Kanto, 1985; Olkkola and Ahonen, 2008). Prolonged or excessive midazolam administration frequently results in increased sedation accumulation and depth, potentially causing delayed recovery, which in turn prolongs hospitalization and precipitates diverse complications (Shehabi et al., 2012). Consequently, it is imperative to investigate the mechanisms underlying 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 via gamma-aminobutyric acid receptor type A (GABAA-R), reducing brain excitability and inducing sedation. GABAA-R is the initiating molecular target of midazolam action. However, the specific mechanism governing the regulatory systems downstream of the GABAergic system in midazolam-induced alterations in consciousness remains to be elucidated. Midazolam elicits an electroencephalographic (EEG) pattern resembling normal non-rapid eye movement (NREM) sleep, lacking a sustained long-range-specific activation pattern compared to wakefulness (Massimini et al., 2012). Therefore, we postulate that a midazolam-induced loss of consciousness, at least partially, involves the activation of an endogenous sleep-promoting pathway.

The locus coeruleus (LC) serves as the primary site for norepinephrine (NE) synthesis and release in the brain, exhibiting extensive projections to various other brain regions (Benarroch, 2018). The LC^NE neurons, which have been linked to multiple functions, including sleep and arousal, stress-related behaviors, attention, and pain conduction, are reportedly instrumental in sleep–arousal regulation (Poe et al., 2020; Suárez-Pereira et al., 2022). Optogenetic activation of LC^NE neurons results in an instantaneous shift from sleep to wakefulness (Carter et al., 2010). The ventrolateral preoptic nucleus (VLPO) in the preoptic hypothalamus is recognized as a pivotal ‘sleep center’ in which sleep-activated neurons orchestrate the initiation and promotion of sleep, and these neurons are subject to regulation by the LC^NE neurons (Chou et al., 2002; Sherin et al., 1996; Sherin et al., 1998). Recently, it has been reported that optogenetic activation of the LC-VLPO NEergic neural circuit facilitates arousal from sleep, mediating its effect through distinct adrenergic receptors, indicating the significance of this neural circuit in controlling wakefulness (Liang et al., 2021). 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 encompasses the utilization of the endogenous sleep-promoting pathway mediated by the LC-VLPO (Nelson et al., 2003). Therefore, these studies offer hints for additional investigation into the role of LC-VLPO NEergic neural circuit in midazolam-induced alterations in consciousness. This will facilitate a more targeted clarification of the neural mechanisms underlying the sedative-hypnotic effects of midazolam, with profound clinical implications.

In the current study, it was unveiled that midazolam initially functioned by acting on GABAA-R in the LC. Crucially, we found that the LC-VLPO NEergic neural circuit plays an important role 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. Initially, we used pharmacological methods to investigate the link between the NE system and awakening from midazolam administration. Subsequently, we adopted more precise and targeted 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 following midazolam administration. In addition, we employed both female and male mice in a series of chemogenetic activation experiments, suggesting that interventions that promoted rebooting from midazolam-induced unconsciousness in male mice were equally effective in female mice. In other words, our findings possess universal applicability and hold significant clinical application value. Based on the above experimental results, we further employed the knockdown technique to specifically manipulate GABAA-R on LC^NE neurons. We found that knockdown GABAA-R not only reduced recovery time from midazolam but also affected calcium signals in NEergic terminals at VLPO. More importantly, specifically block α1-R at VLPO reversed the effect of shortened recovery time produced by GABAA-R knockdown on LC^NE neurons.

These results will significantly enhance our understanding of the neural circuit mechanisms of midazolam-induced altered consciousness and provide a potential target for interventions aimed at addressing delayed recovery caused by midazolam.

Midazolam holds significant potential 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 gradually increasing, the specific neural mechanisms by which it alters consciousness remain unclear. To fill this gap, we opted to investigate 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 current study, we employed a cascade approach, initially utilizing pharmacology and enzyme-linked immunosorbent assay (ELISA), to validate that the central NE system plays an important role in recovery from midazolam sedation. We found that midazolam administration significantly reduced NE content in the brainstem, whereas IP injection of atomoxetine, an NE reuptake inhibitor, could shorten recovery time from midazolam. Conversely, peripheral injection of DSP-4 reverses the pro-recovery effect of atomoxetine. Second, based on calcium signaling, we found a decrease in LC^NE neuronal activity after midazolam administration. Concordantly, optogenetic and chemogenetic activation of LC^NE neurons could facilitate recovery from midazolam, whereas elective ablation of LC^NE 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 LC^NE 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 found that the pro-arousal effect induced by activation of LC^NE 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 GABAergic and NEergic systems co-regulated recovery from midazolam, and GABAA-R on LC^NE neurons and NE α1-R on VLPO were the key points. More importantly, in this study, both male and female mice were used in all chemogenetic activation experiments, and we found that sex discrepancies did not affect the results of the experiment, which signified that the intervention that promoted rebooting from midazolam-induced unconsciousness was equally effective in both male and female mice. Our findings have a universal applicability as well as great clinical translational significance. For the dopamine-beta-hydroxylase (Dbh) promotor applied in the optogenetic and chemogenetic studies, as supported by the literature, Dbh, located in the inner membrane of noradrenergic and adrenergic neurons, is an enzyme that catalyzes the conversion of dopamine to NE, 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 has 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). 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 (Figures 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 nonspecific markers outside the LC were almost absent.

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. The GABAA-R family comprises 19 subunit genes, including α1–6, β1–3, γ1–3, δ, ε, θ, π, and ρ1–3, which assemble to form a pentameric structure (Ghit et al., 2021). 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) one (Sigel and Ernst, 2018). Midazolam is a prevalent psychotropic substance that acts as a positive allosteric modulator of this receptor (Olsen, 2018). The drug binds highly specifically to the BZ-binding site on the GABAA-R complex, modulating 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 effects (Maramai et al., 2020). Notably, β3-knockout mice exhibit a shorter duration of LORR in response to midazolam, suggesting a role of β3-containing GABAA-R in mediating midazolam-induced unconsciousness (Quinlan et al., 1998). 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 elicits a de-consciousness state resembling natural sleep, likely involving 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 remains elusive.

Arousal in the brain depends on many areas that can simultaneously receive diverse signals, with the ascending reticular activating system (ARAS) overseeing arousal and wakefulness maintenance (Lee and Dan, 2012). LC^NE neurons, which are an important component of the ARAS, reportedly play a key role in the maintenance of arousal and alertness (Berridge et al., 2012). Specifically, we posit that LC^NE neurons and their associated circuits are involved in modulating recovery from midazolam. In this study, LC^NE neurons were activated by photostimulation and chemogenetics to rapidly induce the transition from unconsciousness to awakening. As a pivotal arousal center, the LC receives arousal-related inputs and extensively innervates the cerebral cortex and forebrain structures with NEergic projections (Hayat et al., 2020). We initially pharmacologically validated the role of the central NEergic system in modulating midazolam recovery. Subsequently since the LC is the predominant nucleus in the brain for the release of NE, we further demonstrated the role of LC^NE 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.

Given that the VLPO lies downstream of the LC and plays a crucial role in sleep-related information integration, we spotlighted the LC-VLPO neural circuit. The VLPO harbors diverse neuronal populations, including GABAergic and galaninergic neurons, which are recognized as sleep-active neurons (Arrigoni and Fuller, 2022). Intriguingly, there is another cluster of glutamatergic neurons in the VLPO that promote arousal (Chung et al., 2017; Vanini et al., 2020). A recent report showed that LC^NE neurons synergistically facilitate arousal from sleep by simultaneously activating wake-active neurons and inhibiting sleep-active neurons in the VLPO. This regulation of the two types of neurons in the VLPO is mediated by distinct adrenergic receptors (Liang et al., 2021). However, our study differs significantly. First, we demonstrate 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 pinpoints GABAA-R in the LC as a potential key target for midazolam’s effects. 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 LC^NE neurons. Crucially, atomoxetine, a psychotropic drug 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 yield rational therapeutic strategies to prevent delayed recovery. Notably, the VLPO in turn sends GABAergic inhibitory projections to various wake-promoting nuclei throughout the neuroaxis, including the LC (Saper et al., 2005). Studies indicate that the activated VLPO releases GABA to the LC, thus inducing NREM sleep, while NE released from the activated LC inhibits VLPO sleep-active neuron activity and promotes wakefulness (Brown et al., 2012; Van Egroo et al., 2022). As such, a deeper exploration of the interactions between diverse VLPO neuronal populations and their specific connections with the LC is warranted in our study.

The translational implications of a study are indeed a crucial measure of its significance. Our 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 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 managing 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 epilepticus (Conway et al., 2016; Nordt and Clark, 1997; Smith and Brown, 2017). Oral midazolam affects consciousness to a greater or lesser extent, and some suicidal patients have even suffered immediate death from massive doses of midazolam. Our study thus offers valuable insights for medication guidance in such cases.

In summary, our study demonstrates that, in mice, the LC-VLPO NEergic neural circuit contributes to the rapid modulation of altered consciousness induced by midazolam (Figure 10), 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. It suggests a promising new avenue of investigation for the targets of timely recovery from midazolam-induced loss of consciousness, thereby minimizing the risk of delayed recovery and associated complications.

Figure 10

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Data are available at the Dryad website (https://doi.org/10.5061/dryad.2rbnzs7zs).

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Author details

1. LeYuan Gu

   1. Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, China
   2. Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

   Contribution

   Conceptualization, Investigation, Writing – review and editing

   Contributed equally with

   WeiHui Shao, Lu Liu, Qing Xu, YuLing Wang and JiaXuan Gu

   Competing interests

   No competing interests declared

2. WeiHui Shao

   Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

   Contribution

   Data curation, Investigation, Writing – original draft

   Contributed equally with

   LeYuan Gu, Lu Liu, Qing Xu, YuLing Wang and JiaXuan Gu

   Competing interests

   No competing interests declared

3. Lu Liu

   Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, China

   Contribution

   Software, Investigation, Writing – original draft

   Contributed equally with

   LeYuan Gu, WeiHui Shao, Qing Xu, YuLing Wang and JiaXuan Gu

   Competing interests

   No competing interests declared

4. Qing Xu

   Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, China

   Contribution

   Investigation

   Contributed equally with

   LeYuan Gu, WeiHui Shao, Lu Liu, YuLing Wang and JiaXuan Gu

   Competing interests

   No competing interests declared

5. YuLing Wang

   Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

   Contribution

   Investigation

   Contributed equally with

   LeYuan Gu, WeiHui Shao, Lu Liu, Qing Xu and JiaXuan Gu

   Competing interests

   No competing interests declared

6. JiaXuan Gu

   Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

   Contribution

   Investigation

   Contributed equally with

   LeYuan Gu, WeiHui Shao, Lu Liu, Qing Xu and YuLing Wang

   Competing interests

   No competing interests declared

7. Yue Yang

   Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

   Contribution

   Investigation

   Competing interests

   No competing interests declared

8. ZhuoYue Zhang

   Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, China

   Contribution

   Investigation, Writing – original draft

   Competing interests

   No competing interests declared

9. YaXuan Wu

   Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

   Contribution

   Investigation, Writing – original draft

   Competing interests

   No competing interests declared

   "This ORCID iD identifies the author of this article:" 0009-0009-3484-0589

10. Yue Shen

    Department of Anesthesiology, Affiliated Hangzhou First People's Hospital, Westlake University School of Medicine, Hangzhou, China

    Contribution

    Investigation, Writing – original draft

    Competing interests

    No competing interests declared

11. Qian Yu

    Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

    Contribution

    Software, Investigation, Writing – original draft

    Competing interests

    No competing interests declared

12. XiTing Lian

    Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, China

    Contribution

    Investigation

    Competing interests

    No competing interests declared

13. HaiXiang Ma

    Medical College of Jining Medical University, Shandong, China

    Contribution

    Writing – original draft

    Competing interests

    No competing interests declared

14. YuanLi Zhang

    Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China

    Contribution

    Methodology

    Competing interests

    No competing interests declared

15. HongHai Zhang

    1. Department of Anesthesiology, Zhejiang University School of Medicine, Hangzhou, China
    2. Department of Anesthesiology, the Fourth Clinical School of Medicine, Zhejiang Chinese Medical University, Hangzhou, China
    3. Department of Anesthesiology, Affiliated Hangzhou First People's Hospital, Westlake University School of Medicine, Hangzhou, China
    4. Westlake Laboratory of Life Sciences and Biomedicine, Hangzhou, China

    Contribution

    Conceptualization, Resources, Data curation, Supervision, Funding acquisition, Validation, Project administration, Writing – review and editing

    For correspondence

    zhanghonghai_0902@163.com

    Competing interests

    No competing interests declared

    "This ORCID iD identifies the author of this article:" 0000-0003-3530-2060

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