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Xylazine effects on opioid-induced brain hypoxia

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Abstract

Rationale

Xylazine has emerged in recent years as an adulterant in an increasing number of opioid-positive overdose deaths in the United States. Although its exact role in opioid-induced overdose deaths is largely unknown, xylazine is known to depress vital functions and cause hypotension, bradycardia, hypothermia, and respiratory depression.

Objectives

In this study, we examined the brain-specific hypothermic and hypoxic effects of xylazine and its mixtures with fentanyl and heroin in freely moving rats.

Results

In the temperature experiment, we found that intravenous xylazine at low, human-relevant doses (0.33, 1.0, 3.0 mg/kg) dose-dependently decreases locomotor activity and induces modest but prolonged brain and body hypothermia. In the electrochemical experiment, we found that xylazine at the same doses dose-dependently decreases nucleus accumbens oxygenation. In contrast to relatively weak and prolonged decreases induced by xylazine, intravenous fentanyl (20 μg/kg) and heroin (600 μg/kg) induce stronger biphasic brain oxygen responses, with the initial rapid and strong decrease, resulting from respiratory depression, followed by a slower, more prolonged increase reflecting a post-hypoxic compensatory phase, with fentanyl acting much quicker than heroin. The xylazine-fentanyl mixture eliminated the hyperoxic phase of oxygen response and prolonged brain hypoxia, suggesting xylazine-induced attenuation of the brain’s compensatory mechanisms to counteract brain hypoxia. The xylazine-heroin mixture strongly potentiated the initial oxygen decrease, and the pattern lacked the hyperoxic portion of the biphasic oxygen response, suggesting more robust and prolonged brain hypoxia.

Conclusions

These findings suggest that xylazine exacerbates the life-threatening effects of opioids, proposing worsened brain hypoxia as the mechanism contributing to xylazine-positive opioid-overdose deaths.

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Data availability

Raw data and the results of their primary analyses are available on request from Dr. Eugene A. Kiyatkin (NIDA-IRP, NIH; ekiyatki@intra.nida.nih.gov).

Abbreviations

ANOVA:

Analysis of variance

iv:

Intravenous

NAc:

Nucleus accumbens

ip:

Intraperitoneal

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Acknowledgements

The study was supported by the Intramural Research Program of the NIH, NIDA (# 1ZIA DA000566-13 for EAK).

Funding

The study was supported by the Intramural Research Program of the NIH, NIDA (NIH Grant 1ZIADA000566-12 for Dr. Eugene A. Kiyatkin).

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Contributions

EAK: Conceptualization, Surgery procedures, Participation in experiments, Data analyses, Writing the manuscript; SC and MRI: Performance of experiments, Data analyses, Graphic work, Histological work, Review and editing the manuscript.

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Correspondence to Eugene A. Kiyatkin.

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Choi, S., Irwin, M.R. & Kiyatkin, E.A. Xylazine effects on opioid-induced brain hypoxia. Psychopharmacology 240, 1561–1571 (2023). https://doi.org/10.1007/s00213-023-06390-y

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