Cannabis is the most frequently consumed illicit drug (1, 2), with over 16 million Americans reporting current use (3). Cultivated from the Cannabis sativa plant, the cannabinoid analog responsible for the euphoric “high” of cannabis is delta-9-tetrahydrocannabinol (delta-9-THC, Δ⁹-THC). A concentration of more than 0.3% of Δ⁹-THC is considered a Schedule I controlled substance under the Controlled Substance Act of 1970 (4) at the federal level and is a Schedule I controlled substance (carrying the highest legal penalties) in 32 states. Schedule I substances are classified as having no medical use and are of high potential for abuse (5). Other cannabinoids of the C. sativa plant, such as cannabidiol (CBD), do not produce intoxicating effects and are federally recognized as a Schedule V substance by the Drug Enforcement Administration (DEA) with a Δ⁹-THC concentration of <0.1% (6) and recognized as legal by the Food and Drug Administration (FDA) when marketed as cosmetic products only (7). CBD is considered illegal if companies try to make health claims about CBD in products as only one product, Epidiolex (an antiepileptic), is FDA-approved for medical treatment (7).

When the Agricultural Improvement Act of 2018, also known as the Farm Bill, removed hemp, a chemovar of C. sativa called C. sativa L., as a controlled substance (8), it created a significant legal loophole for the production of cannabis-derived products. The Farm Bill allowed for C. sativa L (hemp) to be processed and sold into its individual components (such as CBD, hemp seed oil, and fibers for textiles), as long as they contain <0.3% Δ⁹-THC (9). Following the passing of this law, the legal sale of a non-controlled psychoactive substance, delta-8-tetrahydrocannabinol (delta-8-THC, Δ⁸-THC), emerged, gaining popularity in late 2020 (10).

Delta-8-THC is an isomer of delta-9-THC, synthetically formed by the cyclization of CBD to move the double bond from the 9th position to the 8th position within the cyclohexane ring (11), as shown in Figure 1. This changes the molecule to an officially non-controlled substance because it is no longer structurally Δ⁹-THC, despite being a psychoactive substance of the same molecular weight. However, the DEA stated in 2021, in an Interim Final Rule on Δ⁸-THC, that any Δ⁸-THC derived from chemical conversion or synthetic methods is illegal (4). Since Δ⁸-THC occurs in low quantities naturally in the C. sativa L. (hemp) plant (12), the majority of Δ⁸-THC in commerce is synthesized from CBD oil from these hemp plants (10). The DEA essentially contradicts its regulation as it indicates synthetic cannabinoids to be manmade, non-organic, and synthesized in a lab setting (4, 13), a ruling which is also confirmed by the FDA which defines synthetic material to be substances not found in nature (4). These discrepancies provoked a letter to be written by the DEA to the Alabama Board of Pharmacy to clarify that any Δ⁸-THC product would not be considered a Schedule I substance if it was produced from hemp, and contains <0.3% Δ⁹-THC (13).

Unfortunately, without regulation, Δ⁸-THC products can have variability in their concentration. An independent study that tested 51 Δ⁸-THC products found 76% of them contained greater than the legal limit allowed of Δ⁹-THC (14). Furthermore, little is known about the other byproducts created from the cyclization process (15) or other isomers of THC created by the virtue of synthetization. One toxicology study noted that Δ⁸-THC products contain heavy metals such as lead, mercury, and tin (16), which can have detrimental health effects on consumers. Furthermore, residual solvents from the synthesis of Δ⁸-THC could also have potential toxicology that is unknown. The Centers for Disease Control and Prevention (CDC) had 660 exposures to Δ⁸-THC reported in the first 6 months of 2021, of which 18% required hospitalization (17). The CDC warns about the sedative effects of intoxication with Δ⁸-THC, and also warns users who rely on packaging that reporting of Δ⁹-THC concentration may underestimate the total THC concentration and result in the psychoactive potential of the substance being consumed (17).

Despite ongoing uncertainty around Δ⁸-THC legal status and safety, there were 22.3 million internet searches for Δ⁸-THC in the first 8 months of 2021 (18), reflecting the increasing public interest in Δ⁸-THC. It is likely medical providers are seeing more cases of Δ⁸-THC intoxication but documented that reporting of this presentation is limited by the inability of a standard urine drug screen to distinguish between Δ⁸-THC and Δ⁹-THC (19). In forensic cases that required distinction, liquid chromatography with high-resolution mass spectrometry was required to distinguish between Δ⁸-THC and Δ⁹-THC (19), after screening urine immunochemical analysis showed Δ⁸-THC to have >100% cross-reaction to the Δ⁹-THC antibodies (20).

Thus far, there are two published case reports documenting Δ⁸-THC intoxication. The first case describes acute encephalopathy in a pediatric patient following accidental ingestion of Δ⁸-THC gummies (21). The second case report documents a 23-year-old male and a 35-year-old female who self-reported Δ⁸-THC use before presenting with delusions and suicidal ideation that was persistent and resistant to conventional treatment (22). This manuscript also presents three additional cases, in which the chief complaint was psychosis in self-reported Δ⁸-THC users who did not report using other substances, summarized in Table 1.

Cannabinoid receptors are G-protein coupled receptors of the endocannabinoid system, in which the CB₁ receptor has been shown to propagate the psychotropic effects of Δ⁹-THC (23). From the research available comparing Δ⁸-THC to Δ⁹-THC, it appears that Δ⁸-THC acts at both the cannabinoid CB₁ and CB₂ receptors, like Δ⁹-THC (24), but with a weaker affinity at the CB₁ receptor (11, 25). CB₁ receptors are also implicated in pain and sensory perception, emotional regulation, attention and concentration, memory, and mood (26). Δ⁸-THC may have a similar effect on the CB₂ receptor as Δ⁹-THC, but fewer data exist (11). CB₂ receptors are thought to play a role in the inflammatory response (27). Research in mice has shown CB₂ to be part of the biphasic reward response, where lower activation increases dopamine in the nucleus accumbens and high activation is aversive, decreasing dopamine (28). Route of administration may also play a role in the potency of Δ⁸-THC and Δ⁹-THC. Some studies suggest that oral ingestion of Δ⁸-THC or Δ⁹-THC may be more potent than other routes of administration (29, 30) due to the metabolite 11-OH-THC produced from first-pass metabolism. 11-OH-THC has been shown in rat models to have a higher binding affinity for CB₁ receptors, which are associated with the perceived high (11, 31).

Despite Δ⁸-THC being a newer substance of mainstream interest, several limited qualitative studies exist that compared Δ⁸-THC to Δ⁹-THC. The first reported qualitative study of Δ⁸-THC in humans occurred in 1942 by Adams (30). Adams studied male subjects in prison and showed Δ⁸-THC had similar qualitative effects (anxiety, euphoria, disinhibition, loquaciousness, laughter, and drowsiness) on prisoners as Δ⁹-THC. In 1973, Hollister and Gillespie (32) had a limited study of six male subjects, who reported Δ⁸-THC to be approximately two-thirds as potent as Δ⁹-THC based on self-reported symptoms, peak effect, and subjective intensity. However, cannabis is more potent now than four decades ago (1), with estimates of current Δ⁹-THC concentrations up to 20% (3) vs. 0.35% in commonly confiscated marijuana in the 1970s (33). Thus, the similarities reported in early studies may be more pronounced than what might be seen in current comparative studies of Δ⁸-THC and Δ⁹-THC.

Studies of Δ⁸-THC since its 2020 popularity are limited. One survey showed that one in six Δ⁹-THC users report Δ⁸-THC use (34). A survey study by Kruger and Kruger compared Δ⁸-THC with Δ⁹-THC, where participants who use Δ⁸-THC reported similarities in euphoria between the substances, consistent with Adams, Hollister, and Gillespie, without the reported side effects of paranoia and sedation experienced with Δ⁹-THC (10). This study had a homogenous population that over-selected white male subjects with 30% of their study population living in New York State. The demographic clustering noted in this study could suggest specific demographics of the users of Δ⁸-THC. Interestingly, this study touted Δ⁸-THC to be a tool for diversion in line with the ideals of harm reduction due to Δ⁸-THC's non-controlled status. However, for reasons discussed previously, lack of controlled status of a substance does not constitute safety.

The U.S. Food and Drug Administration recognizes Δ⁸-THC as a psychoactive substance and has had increased reporting of adverse experiences in users of hallucinations, increased anxiety, confusion, and loss of consciousness (35). Given that previous studies have shown similar euphoric experiences in users, along with binding to CB₁ and CB₂ receptors, could mean that Δ⁸-THC acts similarly to Δ⁹-THC. There is a strong body of evidence that associates the use of Δ⁹-THC with psychosis (36–42) with the greatest risk stemming from early initiation (43), and frequent use of high-potency Δ⁹-THC (44, 45). There is continued debate on whether there is a causality between Δ⁹-THC use and the emergence of schizophrenia (39, 46–48). Genetic predisposition (44) may also lead users of cannabis to experience worsening psychotic-like experiences. Furthermore, long-term use of Δ⁹-THC can lead to neuropsychological impairment, including reduced executive functioning and difficulties with concentration and memory (2, 49) that may (50) or may not (51) be reversible with abstinence. Based on the current reported data from qualitative studies on Δ⁸-THC, and the new evidence in rat models of cannabinoid receptor bonding of Δ⁸-THC in comparison to Δ⁹-THC, there is a possibility that Δ⁸-THC could also predispose to, or bring out, psychosis and neuropsychological decline similarly to Δ⁹-THC. However, more research is needed to assess if the same risk factors for psychosis and Δ⁹-THC use (frequency, potency, and genetic predisposition) also apply to the risk of psychosis with the use of Δ⁸-THC.

For the patients presented in the cases, all three developed psychotic symptoms concurrently with self-reported Δ⁸-THC use. The first two patients experienced violent behavior that was uncharacteristic per family collateral. The first two patients also experienced auditory and visual hallucinations. It is the standard of care to screen for organic causes of psychosis when a patient presents with visual hallucinations, as visual hallucinations are thought to be half as prevalent as auditory hallucinations within the psychotic disorder spectrum (52, 53). It is possible that Δ⁸-THC contributed to the patient's experience of visual hallucinations. Δ⁹-THC is known to cause transient psychotomimetic experiences such as derealization, depersonalization, dissociation, hallucinations, and paranoia (38), which all of the patients in the cases described did, in some part, report. Given the similarity of Δ⁸-THC to Δ⁹-THC, it is conceivable that Δ⁸-THC elicited or contributed to the symptoms leading to these patients' presentation. However, the psychotic symptoms were not transient and improved only upon initiation of antipsychotics, hence we cannot rule out the influence of the agent on activating a latent or existing primary psychotic disorder.

Acute Δ⁹-THC use can cause the release of dopamine in the brain (28, 54, 55), which may explain why concurrent use reduces the efficacy of antipsychotics and may lead to relapse of psychosis and re-hospitalizations in patients with schizophrenia (56). Again, the similarities between Δ⁸-THC and Δ⁹-THC could suggest that Δ⁸-THC would have comparable effects, which may be illustrated with patient B. Although patient B was non-compliant with his divalproex, and experienced insomnia, he had active antipsychotic coverage by his LAI and yet relapsed with concerning and severe psychotic symptoms. It is within reason to think that the Δ⁸-THC gummies he had been using were contributory, especially considering patient B has not relapsed on a different LAI post-hospitalization while abstaining from Δ⁸-THC use.

Patient A had no previous psychiatric history, no family history of psychosis, and no history of prodromal symptoms, and started using Δ⁸-THC around the same time he started to experience psychotic symptoms. The precise timing of the onset of symptoms in relation to his Δ⁸-THC use is unclear; however, patient A had a prolonged hospitalization due to psychosis and surreptitiously discarded his antipsychotic medication. Once he started reliably receiving regular doses of his medication, his symptoms appeared to resolve quickly. Finally, patient C was not compliant with his aripiprazole at home but was on a potentially sub-therapeutic dose to treat his schizoaffective disorder (57). His symptoms resolved quickly with hospitalization, and the patient began to suspect his thoughts were incorrect even before re-starting his aripiprazole. As one would expect aripiprazole to take longer than 2 days to help reduce the severity of delusions (58), perhaps abstaining from Δ⁸-THC for several days aided in his thought clarity.

These conclusions from the aforementioned cases are speculative with concern to Δ⁸-THC, and all patients' symptoms could be explained by medication non-adherence and primary psychotic disorders. However, anecdotally, there has been an increase in the use of Δ⁸-THC within our patient population, and the large body of evidence on cannabis (Δ⁹-THC) association with psychosis and schizophrenia cannot be ignored. Furthermore, other cases exist documenting similar presentations of patients using Δ⁸-THC (21, 22). A recognized limitation of Δ⁸-THC reporting is that a UDS cannot distinguish Δ⁸-THC from Δ⁹-THC. Another limitation beyond the subjectivity of information obtained for this case report is that samples of the Δ⁸-THC were not collected for toxicology to know the concentration of Δ⁸-THC or Δ⁹-THC within the product. Broader studies on the use of Δ⁸-THC are also difficult, as no ICD-10 code exists for Δ⁸-THC. Further research is needed to study how the balance of activation between CB₁ and CB₂ receptors affects psychotomimetic experiences and how route determines pharmacokinetics, along with clinical data in human models to determine differences in response to Δ⁸-THC and Δ⁹-THC.

It is recommended that providers ask patients or family members specifically about Δ⁸-THC when approaching the social history of the psychiatric interview or medical history. Patients may deny all drug use since Δ⁸-THC is not a controlled substance, have a positive UDS for THC, and could present with symptoms as described earlier. By asking directly about Δ⁸-THC, providers can use ICD-10 code F12.92 to denote cannabis use, unspecified with intoxication, and report synthetic cannabinoid Δ⁸-THC as part of further comments under the diagnosis within the electronic medical record. Finally, this and other reports suggest that tighter regulation be placed on substances synthesized from hemp and that the federal government confirm their classification of synthesized substances through the DEA and FDA. This may help with legislation at the local and state levels, as well as regulation of delta-8 products, to ensure consistency and standard of product for the safety of the user.

The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding author.

Written informed consent was obtained from the individual(s) for the publication of any potentially identifiable images or data included in this article.

CM, BrB, and BaB were involved in the assessment and medication management of the patients. CM wrote the first draft of the manuscript. BrB, BaB, and RF contributed to the preparation of the manuscript and have approved the final version of the manuscript. All authors contributed to the article and approved the submitted version.