Advertisement
Research Article50th Anniversary Celebration Collection—Minireview

COVID-19 Vaccines and the Virus: Impact on Drug Metabolism and Pharmacokinetics

Eliza R. McColl, Maria A. Croyle, William C. Zamboni, William G. Honer, Mark Heise, Micheline Piquette-Miller and Kerry B. Goralski
Drug Metabolism and Disposition January 2023, 51 (1) 130-141; DOI: https://doi.org/10.1124/dmd.122.000934

Abstract

This article reports on an American Society of Pharmacology and Therapeutics, Division of Drug Metabolism and Disposition symposium held at Experimental Biology on April 2, 2022, in Philadelphia. As of July 2022, over 500 million people have been infected with SARS-CoV-2 (the virus causing COVID-19) and over 12 billion vaccine doses have been administered. Clinically significant interactions between viral infections and hepatic drug metabolism were first recognized over 40 years ago during a cluster of pediatric theophylline toxicity cases attributed to reduced hepatic drug metabolism amid an influenza B outbreak. Today, a substantive body of research supports that the activated innate immune response generally decreases hepatic cytochrome P450 activity. The interactions extend to drug transporters and other organs and have the potential to impact drug absorption, distribution, metabolism, and excretion (ADME). Based on this knowledge, altered ADME is predicted with SARS-CoV-2 infection or vaccination. The report begins with a clinical case exploring the possibility of SARS-CoV-2 vaccination increasing clozapine levels. This is followed by discussions of how SARS-CoV-2 infection or vaccines alter the metabolism and disposition of complex drugs, such as nanoparticles and biologics and small molecule therapies. The review concludes with a discussion of the effects of viral infections on placental amino acid transport and their potential to impact fetal development. The session improved our understanding of the impact of emerging viral infections and vaccine technologies on drug metabolism and disposition, which will help mitigate drug toxicity and improve drug and vaccine safety and effectiveness.

SIGNIFICANCE STATEMENT Altered pharmacokinetics of small molecule and complex molecule drugs and fetal brain distribution of amino acids following SARS-CoV-2 infection or immunization are possible. The proposed mechanisms involve decreased liver cytochrome P450 metabolism of small molecules, enhanced innate immune system metabolism of complex molecules, and altered placental and fetal blood-brain barrier amino acid transport, respectively. Future research is needed to understand the effects of these interactions on adverse drug responses, drug and vaccine safety, and effectiveness and fetal neurodevelopment.

Introduction

Historical Perspectives

Early observations of interactions between infectious diseases and drug metabolism and disposition date to the 1960s and 1970s. These observations included altered quinine metabolism during malaria infection, increased theophylline half-life in children with influenza infection or adenoviral respiratory tract infections, and increased cerebrospinal fluid accumulation of ethambutol and rifampin in tuberculosis meningitis (Brooks et al., 1969; Place et al., 1969; Sippel et al., 1974; Chang et al., 1978). Around the same time period, pioneering work completed by Renton and Mannering discovered that interferon-inducing agents decreased hepatic cytochrome P450 (CYP) activities, paving the way for the idea that inflammatory cytokines are a regulatory link between infectious or inflammatory diseases and hepatic drug metabolism (Renton and Mannering, 1976a, 1976b). Shortly thereafter, the clinical significance of interactions between infections and hepatic drug metabolism were established during a cluster of pediatric theophylline toxicity cases attributed to reduced hepatic CYP1A metabolism amid an influenza B outbreak in 1980 in Seattle, Washington (Kraemer et al., 1982).

In the ensuing years there have been many clinical studies and case reports in adult humans supporting that infections or inflammation downregulate hepatic cytochrome P450 enzymes, although increases in activity have also been reported in some instances (as recently reviewed by Goralski et al., 2018; Lenoir, Rollason, et al., 2021). The observed effects on hepatic CYP metabolism are dependent on the type of inflammatory or infectious stimuli and the specific CYP enzyme (Goralski et al., 2018; Lenoir, Rollason, et al., 2021). The metabolism of CYP3A4, CYP2C19, and CYP1A2 substrates appears to be most affected with lesser or no impact on CYP2C9 and CYP2D6 substrates (Lenoir, Daali, et al., 2021; Lenoir, Rollason, et al., 2021). Most commonly, a temporary reduction in hepatic clearance and prolongation of half-life of elimination is observed. In some cases, the suspected interactions have led to elevated drug levels and drug-related adverse responses as observed for the CYP1A2 substrates theophylline, and clozapine, the CYP2C19 and CYP3A4 substrate voriconazole, and the CYP3A4 substrates tacrolimus and cyclosporine (Lenoir, Rollason, et al., 2021). Similar interactions between infections or inflammation and hepatic cytochrome P450 metabolism are also observed in children but are less well studied overall compared with adults (Lenoir, Rodieux, et al., 2021).

Mechanisms of Interactions

The regulation of hepatic cytochrome P450 metabolism by the innate immune response to infectious and inflammatory stimuli has been studied in preclinical animal models and human cellular models and involves a combination of transcriptional and post-translational mechanisms (Goralski et al., 2018; de Jong et al., 2020) as summarized in Fig. 1 and detailed later. Briefly, pathogen-associated molecular patterns including microbial nucleic acids, lipopolysaccharides, and other virulence factors serve as the primary stimuli and interact with membrane-bound or intracellular pattern recognition receptors (e.g., Toll-like receptors) on host tissue epithelium and tissue resident macrophages to stimulate the innate immune response and ensuing cytokine [e.g., interferons, interleukin (IL)-1β and IL-6, and tumor necrosis factor (TNF)] release (Medzhitov, 2010). In turn, cytokines, bind to their respective receptors on hepatocytes to activate nuclear factor kappa B signaling, which directly represses transcription of some CYPs or reduces the nuclear localization or dimerization of transcription factors including pregnane X receptor, constitutive androstane receptor, and aryl hydrocarbon receptor, resulting in reduced binding to CYP promoter regions and reduced CYP mRNA expression (de Jong et al., 2020; Stanke-Labesque et al., 2020). Direct binding of pathogen-associated molecular patterns to Toll-like receptors (TLRs) on hepatocytes, which activates nuclear factor kappa B signaling, is an additional mechanism whereby CYPs can be downregulated. While not as well studied, epigenetic mechanisms and post-transcriptional regulation of CYP mRNA by microRNAs have also been demonstrated (Stanke-Labesque et al., 2020). In addition, the activation of inducible nitric oxide synthase 2 during the innate immune response increases nitric oxide, which can regulate CYP enzyme function via transcriptional mechanisms, CYP degradation, and catalytic inhibition (Donato et al., 1997; Morgan et al., 2020). The interactions between infectious stimuli are not limited to hepatic metabolism and clearance. Infectious and inflammatory stimuli have been reported to decrease intestinal and hepatic efflux transport, increase renal tubule drug transport, increase or decrease blood-brain barrier drug efflux transport, and decrease placental drug efflux transport (Goralski et al., 2018). Based on these broad interactions, there is potential for viral infections to impact drug absorption, drug distribution, drug metabolism, and drug excretion processes.

Fig. 1.
Fig. 1.

General overview of hepatic CYP regulation by infection and inflammation. NO, nitric oxide; NOS, nitric oxide synthase; INF, interferon.

SARs-CoV-2 Infection and Interactions With Hepatic CYP Metabolism

At the time of writing this article, an estimated 547 million people have been infected with SARS-CoV-2 (the virus causing COVID-19) and over 12 billion vaccine doses have been administered (Soriano et al., 2022). COVID-19 symptoms range from mild or asymptomatic in the least severe cases to acute respiratory distress syndrome and death in the most severe cases (García, 2020; Gao et al., 2021). Based on the understanding of interactions between the innate immune response and hepatic CYP metabolism, the downregulation of hepatic CYPs is probable during SARS-CoV-2 due to increases in systemic concentrations of CYP-regulating cytokines, including IL-1β, IL-6, TNF, and interferon-γ (Huang et al., 2020; Rodrigues et al., 2021). Of particular concern may be patients with severe COVID-19 who experience dysregulated pulmonary and systemic inflammatory responses with elevated IL-6 levels that correlate with disease severity and worse clinical outcomes (Chen et al., 2020; Wu et al., 2020; Lee et al., 2021; Yin et al., 2021). Clinical reports of patients with elevated levels of lopinavir, darunavir, and clozapine during the pandemic provided initial evidence of downregulation of CYP3A4 and CYP1A2 in SARs-CoV-2-infected individuals (Cojutti et al., 2020; Cranshaw and Harikumar, 2020; Gregoire et al., 2020; Marzolini et al., 2020; Schoergenhofer et al., 2020). Adding strength to the initial evidence, a well-designed study that phenotyped SARS-CoV-2-infected patients during and after the infection using the Geneva cocktail approach found reduced CYP3A4, CYP2C19, and CYP1A2 metabolism, respectively, characterized by reduced metabolite to dose ratios of OH-midazolam/midazolam, OH-omeprazole/omeprazole, and paraxanthine/caffeine (Lenoir, Terrier, et al., 2021).

Historically, the impact of vaccines on hepatic CYP metabolism is less clear. As recently reviewed, most human studies or case reports have focused on influenza A vaccine interactions with the CYP2C9 substrate warfarin and CYP1A2 substrate theophylline with fewer studies of other CYPs or other vaccines (Lenoir, Rollason, et al., 2021). Most studies did not find that the pharmacokinetics of drugs were significantly impacted; however, a few smaller studies or case reports suggested that interactions could occur in some individuals depending on patient factors (e.g., age, disease, basal CYP metabolism), drug and vaccine formulation, and time after vaccination (Lenoir, Rollason, et al., 2021). Theoretically, SARS-CoV-2 mRNA and adenoviral vaccine interactions with hepatic CYP metabolism are possible, but there has been a lack of prospective studies in this regard.

The ensuing symposium report begins with a discussion of the impact of SARS-CoV-2 infection and emergency use SARS-CoV-2 vaccines on hepatic CYP450 expression and function and explores the potential clinical implications of such interactions through discussion of a case report of transiently high clozapine levels in a patient treated with SARS-CoV-2 vaccine. Next, the role of the innate immune system in COVID-19 infections and the disposition of complex drugs discusses emerging evidence of inhibition of clearance of nanoparticles and biologic therapies following SARS-CoV-2 infection and the potential risk for drug-related toxicities. The report concludes with a discussion of the effects of viral infections on placental amino acid transport and their potential to impact fetal development and a summary of unanswered questions and future research questions.

A Case Report Exploring the Possibility of SARS-CoV-2 Vaccination Increasing Clozapine Levels (W.G.H.)

Despite the challenges of prescribing and demands for monitoring, clozapine retains a unique place among antipsychotic drugs on account of proven efficacy in schizophrenia with limited response to other antipsychotic medications (Wagner et al., 2021). Side effects include metabolic disorders and weight gain and effects on gastrointestinal, cardiovascular, pulmonary, neurologic, and hematologic systems (Gurrera et al., 2022). Some side effects are associated with dose or plasma level; others are more pronounced during dose-escalation phases of treatment. Neurologic, dose-related side effects of clozapine include sedation; abnormalities in the electroencephalogram; seizures; myoclonus; obsessive-compulsive symptoms; delirium; and, through innervation of other organ systems, tachycardia, orthostatic hypotension, hypersalivation, and enuresis (Tio et al., 2021; Gurrera et al., 2022).

The risk of hematologic side effects requires monitoring of white blood cell and absolute neutrophil counts during clozapine treatment. Following initiation of clozapine treatment, white blood cell counts (including neutrophils) typically rise slightly over the first week, fall to a slightly lower level than baseline over the second week, and return to baseline at the end of the second week (Blackman et al., 2021). During the first 6 weeks of treatment, levels of the cytokines TNF and IL-6 rise, as does the level of the cytokine receptor soluble IL-2 (Røge et al., 2012). At steady state, the risk of neutropenia and, rarely, agranulocytosis persists. The levels of immunoglobulins IgA, IgM, and IgG are slightly low, as are the levels of class-switched memory B-lymphocytes (Ponsford et al., 2018; Ponsford et al., 2019).

Clozapine levels in blood are sensitive to activity of the main metabolizing enzyme, CYP1A2 (Eiermann et al., 1997). This activity is in turn sensitive to inhibition by drugs such as fluvoxamine and to stimulation by exposure to smoked tobacco. Infection can increase clozapine levels in blood through an immunologic cascade, beginning with antigen-presenting dendritic cells releasing cytokines detected by receptors in hepatocytes, leading to transcription factor expression and down-regulation of CYPs (Renton, 2005). An increase in the ratio of clozapine to the primary metabolite norclozapine suggests inhibition of CYP1A2 activity (Stanke-Labesque et al., 2020). During infection and inflammation, hepatocytes simultaneously release C-reactive protein, a biomarker indexing the inflammatory response (Sproston and Ashworth, 2018).

The COVID-19 pandemic created multiple challenges for clozapine treatment. The first was concern for continued access to hematologic monitoring, resulting in a recommendation from an international working group for less frequent monitoring in well-stabilized patients (Siskind et al., 2020). An early retrospective cohort study raised concern that the usual hematologic side effects of clozapine could increase risk for SARS-CoV-2 infection; this was not supported by a much larger study of antipsychotic-treated patients with severe infection (Govind et al., 2021; Ohlis et al., 2022). Clozapine-treated patients experiencing SARS-CoV-2 infection had a small decrease in neutrophils and lymphocytes over the first 7 days after becoming symptomatic, with return to normal levels by 14 days (Gee and Taylor, 2021). However, case reports indicated clozapine levels could rise as much as 3-fold during SARS-CoV-2 infection, with an increase in the clozapine:norclozapine ratio (Tio et al., 2021). Dose reduction was recommended for clozapine-treated patients experiencing signs and symptoms consistent with clozapine toxicity (Siskind et al., 2020; Veerman et al., 2022).

Not surprisingly, the cellular and molecular response to vaccination for SARS-CoV-2 shares features of infection (Sahin et al., 2020). Neutrophils increase slightly and lymphocytes decline after 2 days, returning to normal after 8 days. Cytokine release occurs, and C-reactive protein rises transiently at day 2. These observations during the registration studies of an mRNA vaccine suggested that similar effects in clozapine-treated patients could be associated with increased clozapine level and possible toxicity. We reported a case with findings suggestive of such an effect (Thompson et al., 2021).

In brief, a 51-year-old nonsmoking man with a long history of schizoaffective disorder had been treated with clozapine for over 10 years. He received an mRNA vaccine (Pfizer-BioNTech) for SARS-CoV-2, and 4 days later developed delirium, falls, incontinence, and tachycardia (pulse rate 129/min). He was hospitalized due to concern for infection as the cause of these symptoms; however, repeated SARS-CoV-2 PCR tests were negative, as were other tests for infection. Figure 2 provides a graphical representation of risk factors, clinical and laboratory findings, and course of illness in 4 domains: (a) diagnosis of the presenting problem, (b) patient-related factors, (c) comorbidities, and (d) treatment related (vaccine and clozapine) (Thompson et al., 2021). Past experience included a non-COVID pneumonia 3 months previously, with elevation of neutrophils and slight lowering of lymphocytes, associated with a high C-reactive protein level, as expected with an acute infection. As well, the clozapine level and clozapine:norclozapine ratio were elevated. Of note, following the resolution of pneumonia, the clozapine:norclozapine ratio remained >2.0, suggesting the patient was a slow metabolizer of clozapine at baseline. Multiple comorbidities were noted, with sleep apnea possibly increasing risk for neurologic toxicity of clozapine. Elevation of clozapine level and clozapine:norclozapine ratio was detected on admission, as well as a high C-reactive protein level and neutrophil/lymphocyte responses similar to the previous pneumonia, all consistent with the pathway from immune stimulation to CYP inhibition described earlier. Interestingly, a computed tomography scan revealed an unsuspected normal pressure hydrocephalus, a neurologic finding that could also contribute to the risk for delirium and other symptoms associated with an acute increase in clozapine level. Clozapine was held for 2 days, the level fell from 1078 ng/mL (3296 nM/L) to 396 ng/mL (1212 nM/L), and the clozapine:norclozapine ratio declined from 3.75 to 1.57. The symptoms of toxicity cleared.

Fig. 2.
Fig. 2.

Aggregate illustration of clinical and laboratory findings in a case of delirium developing four days after SARS-CoV-2 vaccination. Laboratory findings relevant to the diagnostic process are illustrated in graphs, the computed tomography scan shows evidence of an unsuspected structural brain abnormality, normal pressure hydrocephalus. PMN, neutrophils; lym, lymphocytes; -3mon, 3 months prior to vaccination baseline; GERD, gastroesophageal reflux disease; pre-vacc, prevaccination.

This single case study provides a temporal sequence of associations that support transient clozapine toxicity as the origin of symptoms. Adopting the approach to clinical and laboratory findings illustrated in Fig. 2 is analogous to an organizational strategy used to report the clinical expression of pathophysiology in HIV-related neuropsychiatric disorders and may have wider value (Ances and Letendre, 2019). Observations from case studies need to be supported or discounted based on findings in larger cohort studies. A report of the effects of SARS-CoV-2 vaccines in 139 patients treated with clozapine found no clinically significant changes in symptoms or hematologic parameters but did support the observation from the present case of an increase in median clozapine level (after second dose) of effect size 0.28 and P = 0.003 (Veerman et al., 2022). Larger studies such as this could provide the opportunity to investigate potentially complex interactions that could occur with CYP1A2 activity depending on concurrent exposures, such as the smoking status of patients. To summarize, case-based and cohort studies conclude that SARS-CoV-2 vaccination is indicated and safe in patients treated with clozapine, and supplementing with reminders on watching for symptoms or signs of clozapine toxicity after vaccination may be a useful precautionary measure to help maintain patients safely on clozapine therapy.

Impact of Emerging Infections and Vaccines on CYP450 Metabolism (M.A.C.)

People with highest risk of complications from COVID-19 are those with underlying medical conditions (cardiovascular disease, diabetes, hypertension, chronic lung disease) that require use of several medicinal agents for maintenance therapy (Peng et al., 2021; Touyz et al., 2021; Conway et al., 2022; Gęca et al., 2022). Although there are few studies in the literature that specifically focus on how virus infection impacts hepatic and renal drug metabolism, there are data to suggest that drug metabolism will be impacted during various stages of SARS-CoV-2 infection and after administration of emergency use vaccines.

Active Infection

The most obvious time of concern is during active infection with SARS-CoV-2, virus production and shedding starts several days before the inflammatory phase where circulating cytokines can suppress hepatic and renal drug metabolism (Fig. 3). However, changes in CYP expression and function could start as soon as SARS-CoV-2 enters the kidney and liver tissues as the spike protein has been shown to engage integrins as well as angiotensin-converting enzyme 2 receptors for cell entry (Fig. 4A) (Liu et al., 2022). Integrins are heterodimeric receptors, consiting of an α and β subunit (Fig. 4B). Activation of the integrin receptors is tightly regulated and bidirectional and is mediated through binding of external stimulators (virus, bacteria, arginine-glycine-aspartic acid–rich peptides) or internally through the binding of the intracellular protein talin with the β subunit of the receptor (Kadry and Calderwood, 2020). Talin-mediated signaling is essential for productive SARS-CoV-2 infection, and evidence suggests it serves as a molecular link between infection and CYP3A function (Simons et al., 2021). In support of this, the removal of arginine-glycine-aspartic acid integrin binding domains from the capsid of a recombinant adenovirus and treatment of human hepatocytes with small interfering RNA specific for the β subunit of integrin receptors reversed the suppression of CYP3A activity and expression normally seen during infection in mice (Jonsson-Schmunk et al., 2016). Additionally, new data from our laboratory show that silencing of talin in uninfected human hepatocytes increases CYP3A4 metabolic capacity 2.5-fold (Fig. 4C). Taken together, this suggests that the ability of drugs to be cleared by the kidney or the liver is compromised at the time the virus spike protein engages integrin receptors (Fig. 4A). Cytokine production in response to the virus further establishes this effect (Fig. 3). While hepatic and renal CYPs have been shown to return to baseline levels once virus infection has resolved (Callahan et al., 2005; Le et al., 2006; Croyle, 2009), the suppression of CYPs may be extended in the case of severe and postacute COVID-19 syndrome (PACS), both characterized by hyper- and extended inflammatory states (Fig. 3) (Nalbandian et al., 2021; Lamers and Haagmans, 2022).

Fig. 3.
Fig. 3.

Time course of SARS-CoV-2 infection with respect to severity of disease: virus shedding, inflammatory phase, symptom development and therapies. Note the inflammatory phase lasts approximately 15 days in mild cases and is more amplified and extensive in severe cases suggesting that CYP mediated metabolism could be altered for extensive periods of time even with mild infections. Image source: Hulo et al. (2011).

Fig. 4.
Fig. 4.

Engagement of integrins by the SARS-CoV-2 spike protein could induce changes in hepatic CYP expression and function. (A) SARS-CoV-2 spike protein facilitates virus entry through engagement of beta integrins and angiotensin converting enzyme 2 (ACE2) receptors. (B) Engagement of integrins through the spike protein stimulates outside in cell signaling pathways that can suppress CYP expression and function. Talin can engage integrins from the cytoplasm and alter CYP through inside out signaling pathways. (C) Suppression of talin in human hepatocytes increases CYP activity suggesting that this protein, which supports SARS-CoV-2 infection, plays a notable role in the regulation of CYP.

Postacute COVID-19 Syndrome/Reinfection

The US Centers for Disease Control and Prevention defines PACS as a variety of new, returning, or ongoing health problems that people experience 4 or more weeks after first being infected with SARS-CoV-2, while the World Health Organization defines it as a condition that occurs 3 months from the onset of symptomatic COVID-19 that lasts for at least 2 months and cannot be explained through alternative diagnosis (Chippa et al., 2022; Soriano et al., 2022). PACS is associated with persistent virus, viral antigen, and viral RNA in tissues such as the liver and kidney that create chronic inflammation as well as autoimmune states (Ramakrishnan et al., 2021; Copur et al., 2022). This provides the conditions that could lead to a prolonged significant impairment of CYP expression and activity in patients with PACS. It is also important to note that postacute syndromes also occur with other viral pathogens such as West Nile and influenza viruses (Choutka et al., 2022). To date, the impact of PACS on renal and hepatic drug metabolism has not been evaluated in animal models of disease or the clinic. As the pandemic progressed, reports of reinfection with different SARS-CoV-2 variants and breakthrough infections in vaccinated patients occurred at an increasing rate (Negi et al., 2022; Mohseni Afshar et al., 2022). Although this phenomenon is common with other viruses such as influenza, the impact of reinfection on hepatic and renal drug metabolism has not yet been evaluated.

Immunization

To date, over 12 billion people have received at least 1 dose of a COVID-19 vaccine with approximately 5 billion successfully receiving a complete initial protocol (Mathieu et al., 2021). The most commonly observed adverse reactions to these vaccines include erythema, fever, fatigue, headache, and hypersensitivity reactions (Kouhpayeh and Ansari, 2022; Lau and Vadlamudi, 2022). These types of reactions are transient and usually resolve within 48 to 72 hours. They are also commonly associated with other vaccines and are caused by the production and release of cytokines into the circulation (Institutes of Medicine, 2012; Herve et al., 2019). While several reports have described interactions between drugs with narrow therapeutic windows and influenza vaccines (Raaska et al., 2001; Robertson, 2002; Carroll and Carroll, 2009), these results have not been able to be fully replicated in controlled clinical trials (Stults and Hashisaki, 1983; Gomolin et al., 1985; Soontornpun et al., 2020), which suggests that patient-specific characteristics such as altered drug clearance prior to immunization may also be required for notable observation of changes in CYP soon after immunization (Meredith et al., 1985). To date, the impact of boosting doses of a vaccine has not been investigated in the clinic or in animal models of drug metabolism.

Different COVID-19 vaccines may alter CYP enzymes in different ways. Studies in which the Ebola Zaire glycoprotein was expressed from a recombinant adenovirus vaccine (similar in approach to the Janssen and Astra Zeneca COVID-19 vaccines) found that hepatic CYP enzymes were mildly suppressed in mice 24 hours after immunization and resolved by 48 hours (Jonsson-Schmunk et al., 2021). Treatment with glycoprotein alone at concentrations found in the circulation of immunized individuals significantly induced CYP3A4 in human hepatocytes while treatment with a H1N1 human influenza virus almost completely shut down CYP expression and activity. Influenza held such a profound effect on CYP through its ability to control RNA translation capacity within the cell during active infection. This, paired with the fact that specific components of the lipid nanoparticles in which the Moderna and Pfizer vaccines were formulated triggered a broad inflammatory response (Jonsson-Schmunk et al., 2021; Kenigsberg et al., 2022; Padin-Gonzalez et al., 2022; Szebeni et al., 2022; Tahtinen et al., 2022) suggests that these vaccines have the potential to significantly impact hepatic and renal CYP-mediated drug metabolism. This is just starting to be reported in the clinic as demonstrated through the clozapine case report in the previous section. Further study of the impact of SARS-CoV-2 infection and immunization are currently underway in relevant animal models of disease that also correlate with human CYP expression and activity patterns (Tiwari et al., 2022).

Role of the Innate Immune System in COVID-19 Infections and the Disposition of Complex Drugs (W.C.Z. and M.H.)

The innate immune system is involved in the recognition, uptake, and clearance of a wide range of pathogens and substances, such as bacteria, viruses, nanoparticles, and biologics (Lucas et al., 2015; Madden et al., 2017; Lucas et al., 2018). Antigen-presenting cells of the innate immune system are the first line of contact and mediators of the immune response against the viruses, such as the coronavirus (Fig. 5) (Arancibia et al., 2007; Takeuchi and Akira, 2009). There is high variability in the infection rate, severity, and response to treatment of COVID-19 (Kakodkar et al., 2020; Zimmer, 2020; Rahman et al., 2021). The most severe cases of COVID-19 appear to include an overreactive or hyperinflamed immune response in the lungs that lead to severe pneumonitis and death.

Fig. 5.
Fig. 5.

The Innate immune system is the first line of defense against pathogens, such as viruses. The innate immune system response activates adaptive immune processes through Toll-like receptors (TLRs) and antigen presentation. Innate immune cells recognize and phagocytose pathogens that promote cytokine and antigen presentation to T cells. In addition, these same innate immune cells are directly involved in the identification, uptake, and clearance of complex drugs (e.g., nanoparticles, conjugates, biologics).

Drug metabolism and disposition can be altered by the innate immune system, which is the primary pharmacokinetic clearance pathway for complex drugs (e.g., nanoparticles, conjugates, and biologics) (Lucas et al., 2015; Lucas et al., 2018). Patients with SARS-CoV-2 infections may have altered innate immune system function and phenotypes, which alters the recognition, uptake, and clearance of nanoparticles and biologics, putting them at higher risk for suboptimal response or drug-related toxicities. This section describes factors that alter the function of the innate immune system, the interaction between the innate immune system and complex drugs, and the effects of SARS-CoV-2 on the innate immune system and alteration of the pharmacokinetics of complex drugs, such as Pegylated (PEG)-liposomal doxorubicin (Doxil) and monoclonal antibodies and antibody drug conjugates (ADCs).

Biomarkers of Innate Immune System

There is a high (approximately 10-fold) interpatient variability in the phenotype of function (e.g., phagocytosis, reactive oxygen species generation) and surface receptors (e.g., FcɣRs) of innate immune system cells in blood and tissues (Lucas et al., 2015; Lucas et al., 2018). This variability in the innate immune system biomarkers is associated with high variability in immune response and pharmacology of nanoparticles, viral drug carriers, and antibodies that are identified and taken up by the innate immune system cells (Lucas et al., 2015; Madden et al., 2017; Lucas et al., 2018). Moreover, the increased severity and death rate of COVID-19 in male patients and overweight patients are consistent with our results of higher innate immune system function as measured by the biomarkers in these patient groups (Zamboni et al., 2009; La-Beck et al., 2012; Klang et al., 2020; Papadopoulos et al., 2021). Thus, we hypothesized that interactions between the SARs-CoV-2 virus and the innate immune system will alter the function of the innate immune system and change the pharmacokinetics and pharmacodynamics of complex drugs, such as PEG-liposomal doxorubicin and antibodies/ADCs.

Effect of SARs-CoV-2 Infection on Innate Immune System Function and Pharmacokinetics of PEG-Liposomal Doxorubicin in Mice

Viral load and biomarkers of the innate immune system were evaluated on days 2 and 4 in MA-10 mouse adapted SAR-CoV-2 in wild type BALB/c mice (n = 4/time point) infected with and without SARS-CoV-2 virus (Leist et al., 2020). Viral load was measured by quantitative reverse transcriptase polymerase chain reaction (Geng et al., 2021). Biomarkers of innate immune system function in blood (phagocytosis of monocytes) was evaluated using previously validated and published methods (Caron et al., 2013; Lucas et al., 2017). Previously published models describing the relationship between innate immune system function (phagocytosis of monocytes in blood) and the disposition of PEG-liposomal doxorubicin in plasma was used to simulate the plasma pharmacokinetic disposition of PEG-liposomal doxorubicin in mice with and without SARS-CoV-2 virus infection.

The SARS-CoV-2 virus load on days 2 and 4 after infection were 1,493,750 ± 379,487 and 209,000 ± 321,775 plaque-forming units, respectively. Phagocytic function was similar in infected and noninfected mice on day 2 post-infection (P > 0.05). However, on day 4 post-infection the phagocytic function was 2.3-fold higher in the infected mice (67,425 ± 18,379 mean fluorescence intensity) compared with non-infected mice (29,283 ± 4,338 mean fluorescence intensity) (P < 0.001). Interestingly, on day 4 post-infection, there appears to be a slight inverse relationship between viral load and phagocytic function in monocytes in blood (Fig. 6). Thus, the amount of viral load may also affect the degree of change in innate immune system function and change in pharmacokinetics and pharmacodynamics of complex drugs. Based on our prior studies measuring and modeling the relationship between phagocytic function of monocytes in blood and the pharmacokinetics of PEG-liposomal doxorubicin in plasma of mice and humans, pharmacokinetic simulations predict that the 2.3-fold higher phagocytic function in infected mice will increase PEG-liposomal doxorubicin clearance by approximately 2-fold and decrease the plasma exposure of PEG-liposomal doxorubicin by at least half compared with noninfected mice (Fig. 7). These results strongly suggest that COVID-19 infection alters the function of the innate immune system, which would then alter the pharmacokinetics and pharmacodynamics of complex drugs, such as PEG-liposomal doxorubicin. Thus, the doses of complex drugs designed for noninfected patients may not be optimal for patients with COVID-19.

Fig. 6.
Fig. 6.

The relationship between viral load measured by plaque-forming units (PFU) and phagocytic function [mean fluorescence intensity (MFI)] of monocytes in blood of infected mice on day 4 post infection. There is a slight inversion relationship between viral load and phagocytic function. Thus, the amount of viral load may also affect the degree of change in innate immune system function and change in pharmacokinetic and pharmacodynamic disposition of complex drugs.

Fig. 7.
Fig. 7.

Simulated plasma concentration versus time curves of liposomal encapsulated doxorubicin in mice. Noninfected mice administered a single intravenous dose of PEG-liposomal doxorubicin (6 mg/kg) are shown by the black line. Infected mice administered a single intravenous dose of PEG-liposomal doxorubicin (6 mg/kg) are shown in red. Infected mice administered a single intravenous dose of PEG-liposomal doxorubicin (12 mg/kg) are shown in green.

Impact and Future Directions

The ultimate goal of this research is to translate the biomarkers of the innate immune system evaluated in this study into novel clinical tests that predict variability and changes in innate immune system function in patients with and without COVID-19 and other types of infections. These results can then be used to optimize the dose of complex drugs in these patient populations. Ongoing studies are evaluating the pharmacokinetic disposition of PEG-liposomal doxorubicin in plasma and tissue (e.g., liver, spleen, and lung, which are the primary organs of the innate immune system and depot sites for complex drugs, such as PEG-liposomal doxorubicin) in mice without and with infection with SARS-CoV-2 virus to validate the simulated plasma pharmacokinetic results and to evaluate the disposition PEG-liposomal doxorubicin in tissues. In addition, other biomarkers of PEG-liposomal doxorubicin and innate immune system function and phenotype in blood, liver, spleen, and lungs are also being evaluated for other complex drugs including antibodies and ADCs.

It is important to understand the acute (e.g., a few days post-infection), late (e.g., weeks post-infection), and prolonged (e.g., months to years) effects of SARS-CoV-2 infection on the function of the innate immune system and alteration in the pharmacokinetics and pharmacodynamics of complex drugs (Healey et al., 2022). It is also important to understand these effects in asymptomatic SARS-CoV-2-infected patients who may be more likely to undergo treatment of their underlying disease (Gao et al., 2021). As the COVID-19 vaccines by Moderna and Pfizer/BioNTech are nanoparticle or carrier agents, it would be important to understand how these and other nanoparticle-based vaccines alter the innate immune system and potentially the pharmacokinetic disposition, efficacy, and toxicity of complex drugs in the general population, but especially in high-risk populations, such as obese or immune-suppressed patients, who may already have an altered innate immune system (Meo et al., 2021).

Infection During Pregnancy Downregulates the Expression of Amino Acid Transporters in Rat and Human Placentas (E.R.M. and M.P-M.)

Infection with SARS-CoV-2 and resulting COVID-19 carries an increased risk during pregnancy. Pregnant people who are infected with SARS-CoV-2 have an increased risk of severe COVID-19, including increased risk of hospital admission and intensive care unit admission and requiring mechanical ventilation (Safadi et al., 2022). Moreover, despite the fact that risk of vertical transmission of SARS-CoV-2 is estimated to be under 5%, maternal infection during pregnancy also increases the risk of negative fetal outcomes including preterm birth, decreased birth weight, fetal distress in labor, neonatal intensive care unit admission, and stillbirth (Giuliani et al., 2022; Safadi et al., 2022). Additionally, it is possible that prenatal SARS-CoV-2 infection may have long-term implications for offspring neurodevelopment. It is well established that various bacterial and viral infections, when contracted during pregnancy, increase the chance of the offspring having a neurodevelopmental disorder such as autism spectrum disorder or schizophrenia (Sorensen et al., 2009; Atladóttir et al., 2010; Brown and Derkits, 2010; Jiang et al., 2016; Giuliani et al., 2022). Emerging evidence suggests that offspring resulting from pregnancies complicated by COVID-19 may exhibit developmental delays, implying that SARS-CoV-2 infection may similarly increase the chance of neurodevelopmental disorders (Edlow et al., 2022). However, as with the other infections linked to changes in offspring neurodevelopment, how infection during pregnancy alters fetal brain development is unclear.

The gold standard model for investigating the link between viral infection during pregnancy and neurodevelopmental changes involves rodents receiving prenatal administration of the synthetic, double-stranded RNA molecule polyinosinic:polycytidylic acid [poly(I:C)]. Poly(I:C) stimulates toll-like receptor 3 (TLR3), the same receptor stimulated by many viruses, including SARS-CoV-2 (Bortolotti et al., 2021). While SARS-CoV-2 also stimulates toll-like receptor 7 (TLR7, which senses single-strand RNA), an animal model of TLR7 agonism during pregnancy has yet to be extensively characterized. Administration of poly(I:C) during pregnancy results in altered offspring behavior and neurobiology which is consistent with neurodevelopmental disorders such as autism spectrum disorder and schizophrenia (Careaga et al., 2017; Haddad et al., 2020). Using the poly(I:C) rodent model, studies have concluded that the link between prenatal infection and neurodevelopmental disorders is due to activation of the maternal immune system itself, termed “maternal immune activation,” as opposed to the presence of a particular pathogen. However, how maternal immune activation alters fetal brain development remains unknown.

A potential link between maternal immune activation and neurodevelopmental changes may lie in changes to transport of essential nutrients across the placenta. During pregnancy, the placenta supports fetal development by acting as a protective barrier between maternal and fetal circulation and facilitating exchange of nutrients and waste. To support both functions, the placenta expresses a number of ATP-binding cassette (ABC) and solute carrier (SLC) drug and nutrient transporters (Lager and Powell, 2012; Dallmann et al., 2019). Inflammation and infection has been shown to alter expression of drug transporters in the placenta (Petrovic and Piquette-Miller, 2010; Evers et al., 2018), resulting in altered fetal drug exposure (Petrovic and Piquette-Miller, 2015). In contrast, the impact of infection or inflammation on placental nutrient transporters is less well characterized.

Amino acid transport across the placenta is best conceived through a systems approach, in which the concerted effort of accumulative transporters, exchangers, and facilitated transporters with overlapping substrate specificity drive a net transport of amino acids from maternal to fetal circulation (Cleal et al., 2018). Amino acid transporters are also expressed in the fetal brain at the blood-brain barrier, where they facilitate amino acid transport into and out of the fetal brain (Campos-Bedolla et al., 2014), as well as at neuronal synapses, where they help regulate neurotransmission (Nguyen et al., 2021). Regulation of amino acid transport across the placenta and throughout the fetal brain is essential, as amino acids are required for fetal brain development (McDonald and Johnston, 1990; Kurbat and Lelevich, 2009; Tabatabaie et al., 2010; Tochitani, 2017). As such, changes in placental or fetal brain amino acid transport could alter fetal access to the amino acids required for neurodevelopment and contribute to a neurodevelopmental disorder. Indeed, amino acid dysregulation has been implicated in both autism spectrum disorder and schizophrenia (Bala et al., 2016; Saleem et al., 2017).

We therefore hypothesized that maternal immune activation associated with prenatal viral infections could alter placental and fetal brain amino acid transporter expression, which could alter brain development. To test this hypothesis, we used the rat poly(I:C) model of maternal immune activation, which is known to cause neurodevelopmental changes in offspring (Haddad et al., 2020). At 24 to 48 hours after poly(I:C) administration, significant decreases in the expression of alanine serine cysteine transporter 1 (ASCT1) and excitatory amino acid transporter 2 (EAAT2) were found in the placenta, with a similar trend for the small neutral amino acid transporter 2 (SNAT2) (McColl and Piquette‐Miller, 2019) (Table 1). Poly(I:C) also imposed significant decreases in the expression of SNAT5, EAAT1, and glycine transporter 1 (GLYT1) in fetal brain. Interestingly, inherited deficiencies in ASCT1, EAAT1 or 2, and GLYT1 are associated with neurologic changes in humans (Yahyaoui and Pérez-Frías, 2019). HPLC analysis of the fetal brains also revealed significant changes in tissue concentrations of multiple amino acids (McColl and Piquette‐Miller, 2019). Of note, poly(I:C)-mediated maternal immune activation altered the levels of several amino acids required for proper brain development. This included a significant decrease in taurine, which is necessary for optimal neuronal proliferation (Tochitani, 2017), as well as significant decreases in glycine and GABA, two neurotransmitters that help regulate fetal brain development (Tochitani, 2017). Moreover, some of the affected amino acids have been implicated in neurodevelopmental disorders. For example, decreased serum taurine levels have been proposed as a biomarker for autism spectrum disorder (Park et al., 2017) and altered GABAergic function has been implicated in both autism spectrum disorder and schizophrenia (Lewis et al., 2005; Cetin et al., 2015). Therefore, placental and fetal brain amino acid transport are altered in a rat model of viral infection that is associated with changes in offspring neurodevelopment.

View this table:
TABLE 1

Summary of changes in amino acid transporter membrane protein expression in the placenta and fetal brain after poly(I:C) administration to ratsa or suspected active infection in humans.b

We next sought to determine whether similar changes occur in human pregnancies complicated by infection. To do so, we obtained human placentas collected at term from pregnancies complicated by chorioamnionitis or suspected active infection of unknown origin and gestational age-matched controls. Chorioamnionitis is characterized by inflammation of pregnancy tissues, including the placenta, typically as a result of an ascending bacterial infection (Cappelletti et al., 2020). Placentas in the suspected infection group were from individuals who had not had an official diagnosis of infection but were experiencing symptoms such as fever, chills, or elevated white blood cell count when they delivered. In line with what we saw in poly(I:C)-treated rats, suspected infection was associated with a significant decrease in membrane protein expression of ASCT1 and a trend toward 50% downregulation of SNAT2 in human placentas (McColl and Piquette-Miller, 2022) (Table 1). In contrast, ASCT1, EAAT2, and SNAT2 expression were unchanged in chorioamnionitis placentas. As many of these individuals were prescribed antibiotics earlier in pregnancy, it is likely that the infection and inflammation were resolved before their placentas were collected at term.

Overall, our results demonstrate that a viral model of maternal immune activation in rats that is known to alter offspring neurodevelopment also exhibits altered placental and fetal brain amino acid transport (McColl and Piquette‐Miller, 2019). These changes are also partially recapitulated in placentas from humans experiencing an active infection (McColl and Piquette-Miller, 2022). Given the importance of amino acids during fetal brain development and their implications in disorders such as autism spectrum disorder and schizophrenia, these changes could contribute to the link between viral infection during pregnancy and offspring neurodevelopmental disorders. Thus, our results demonstrate that subsequent research needs to consider how SARS-CoV-2 infection may impact not only the transport or metabolism of xenobiotics, but also endogenous nutrients, particularly in the context of infection during pregnancy. Whether prenatal SARS-CoV-2 infection will be associated with increases in offspring neurodevelopmental disorders remains to be seen, but long-term follow-up studies tracking neurodevelopment after prenatal COVID-19 are taking place.

Discussion

Emerging research indicates that interactions between SARS-CoV-2 infection or vaccination on hepatic CYP metabolism is possible and can lead to reduced metabolism of small-molecule drugs. Furthermore, through effects on the innate immune system, alteration in the metabolism of complex drugs (e.g., liposomal formulations) are also possible. Despite these advances, there remain several gaps in understanding that should be addressed with future research. There is a need to better understand in which situations and for which drugs these interactions could impact drug safety and effectiveness and if modifications in drug dosing or therapeutic monitoring are required. Additional studies to evaluate the interactions between SARs-CoV-2 and other aspects of drug disposition such as effects on blood-brain barrier drug transporters and renal tubule transporters, and the respective impact on central nervous system drug distribution and renal drug elimination, are required. Research is needed to determine if altered drug disposition persists in individuals with long COVID and if this contributes to observed symptoms associated with long COVID. Additional research on novel mRNA and adenoviral vaccine technologies including booster doses and impacts on the disposition of other drug therapies is also required. Until these questions are answered, it is important to remain aware that SARS-CoV-2 infection mediated interactions with the hepatic CYP metabolism are possible and a potential source of variability in drug responses.

Acknowledgments

We would like to express our sincere thanks to ASPET for hosting and providing financial support for the symposium at Experimental Biology 2022 in Philadelphia. We would like to thank Andrew T. Lucas, Sharon-Taft-Benz, Victoria K. Baxter, and Elizabeth Anderson from the University of North Carolina Chapel Hill for their assistance with the project “Role of the Innate Immune System in COVID-19 Infections and the Disposition of Complex Drugs” and Stephen Schafer from the University of Texas at Austin for the preparation of Figure 4.

Authorship Contributions

Participated in research design: McColl, Croyle, Zamboni, Heise, Piquette-Miller

Conducted experiments: McColl, Croyle, Zamboni, Heise

Performed data analysis: McColl, Croyle, Honer, Zamboni, Heise

Wrote or contributed to writing the manuscript: McColl, Croyle, Honer, Zamboni, Piquette-Miller, Goralski

Footnotes

    • Received May 2, 2022.
    • Accepted September 30, 2022.

  • E.R.M. was a recipient of a Fredric Banting and Charles Best Canada Graduate Scholarship from the Canadian Institutes of Health Research [GSD-164238]. M.A.C. received funding from the American Society of Pharmacology and Therapeutics (David Lehr Research Award) and GlaxoSmithKline and Burroughs Wellcome. W.G.H. was supported through the Jack Bell Chair in Schizophrenia. W.C.Z. received funding from National Institutes of Health, the National Center for Advancing Translational Sciences (NCATS) [UL1TR002489]. M.P-M. received funding from the Canadian Institutes of Health Research [MOP-13346 and PJT-169195]. The content is solely the responsibility of the authors and does not represent the official views of the funding organizations.

  • W.C.Z. is an inventor of the biomarkers of the innate immune system and founder and co-owner of Glolytics, LLC company, which is developing these biomarkers. All other authors have no conflicts to report.

  • 1E.R.M., M.A.C., W.C.Z. and W.G.H. are the co-first authors.

  • dx.doi.org/10.1124/dmd.122.000934.

Abbreviations

ABC
ATP-binding cassette transporter
ASCT
alanine serine cysteine transporter
ADCs
antibody-drug conjugates
EAAT
excitatory amino acid transporter
GABA
gamma aminobutyric acid
GLYT
glycine transporter
IL
interleukin
PACS
post-acute COVID-19 syndrome
PEG
pegylated
Poly(I:C)
polyinosinic:polycytidylic acid
SLC
solute carrier
SNAT
small neutral amino acid transporter
TLR(s)
Toll-like receptor(s)

References

  1. (2012), in Adverse Effects of Vaccines: Evidence and Causality (Stratton K, Ford A, Rusch E, and Clayton EW eds), Washington (DC).
    1. Ances BM and
    2. Letendre SL
    (2019) CROI 2019: neurologic complications of HIV disease. Top Antivir Med 27:2633.
    OpenUrlPubMed
    1. Arancibia SA,
    2. Beltrán CJ,
    3. Aguirre IM,
    4. Silva P,
    5. Peralta AL,
    6. Malinarich F, and
    7. Hermoso MA
    (2007) Toll-like receptors are key participants in innate immune responses. Biol Res 40:97112.
    OpenUrlPubMed
    1. Atladóttir HO,
    2. Thorsen P,
    3. Østergaard L,
    4. Schendel DE,
    5. Lemcke S,
    6. Abdallah M, and
    7. Parner ET
    (2010) Maternal infection requiring hospitalization during pregnancy and autism spectrum disorders. J Autism Dev Disord 40:14231430.
    OpenUrlCrossRefPubMed
    1. Bala KA,
    2. Doğan M,
    3. Mutluer T,
    4. Kaba S,
    5. Aslan O,
    6. Balahoroğlu R,
    7. Çokluk E,
    8. Üstyol L, and
    9. Kocaman S
    (2016) Plasma amino acid profile in autism spectrum disorder (ASD). Eur Rev Med Pharmacol Sci 20:923929.
    OpenUrl
    1. Blackman G,
    2. Lisshammar JEL,
    3. Zafar R,
    4. Pollak TA,
    5. Pritchard M,
    6. Cullen AE,
    7. Rogers J,
    8. Carter B,
    9. Griffiths K,
    10. Nour M et al.
    (2021) Clozapine response in schizophrenia and hematological changes. J Clin Psychopharmacol 41:1924.
    OpenUrl
    1. Bortolotti D,
    2. Gentili V,
    3. Rizzo S,
    4. Schiuma G,
    5. Beltrami S,
    6. Strazzabosco G,
    7. Fernandez M,
    8. Caccuri F,
    9. Caruso A, and
    10. Rizzo R
    (2021) TLR3 and TLR7 RNA sensor activation during SARS-CoV-2 infection. Microorganisms 9:9.
    OpenUrl
    1. Brer S
    (2014) The SLC38 family of sodium-amino acid co-transporters. Pflugers Arch 466:155172.
    OpenUrlCrossRefPubMed
    1. Brooks MH,
    2. Malloy JP,
    3. Bartelloni PJ,
    4. Sheehy TW, and
    5. Barry KG
    (1969) Quinine, pyrimethamine, and sulphorthodimethoxine: clinical response, plasma levels, and urinary excretion during the initial attack of naturally acquired falciparum malaria. Clin Pharmacol Ther 10:8591.
    OpenUrlPubMed
    1. Brown AS and
    2. Derkits EJ
    (2010) Prenatal infection and schizophrenia: a review of epidemiologic and translational studies. Am J Psychiatry 167:261280.
    OpenUrlCrossRefPubMed
    1. Callahan SM,
    2. Ming X,
    3. Lu SK,
    4. Brunner LJ, and
    5. Croyle MA
    (2005) Considerations for use of recombinant adenoviral vectors: dose effect on hepatic cytochromes P450. J Pharmacol Exp Ther 312:492501.
    OpenUrlAbstract/FREE Full Text
    1. Campos-Bedolla P,
    2. Walter FR,
    3. Veszelka S, and
    4. Deli MA
    (2014) Role of the blood-brain barrier in the nutrition of the central nervous system. Arch Med Res 45:610638.
    OpenUrlCrossRefPubMed
    1. Cappelletti M,
    2. Presicce P, and
    3. Kallapur SG
    (2020) Immunobiology of acute chorioamnionitis. Frontiers Immunol 11:649.
    OpenUrl
    1. Careaga M,
    2. Murai T, and
    3. Bauman MD
    (2017) Maternal immune activation and autism spectrum disorder: from rodents to nonhuman and human primates. Biol Psychiatry 81:391401.
    OpenUrl
    1. Caron WP,
    2. Lay JC,
    3. Fong AM,
    4. La-Beck NM,
    5. Kumar P,
    6. Newman SE,
    7. Zhou H,
    8. Monaco JH,
    9. Clarke-Pearson DL,
    10. Brewster WR et al.
    (2013) Translational studies of phenotypic probes for the mononuclear phagocyte system and liposomal pharmacology. J Pharmacol Exp Ther 347:599606.
    OpenUrlAbstract/FREE Full Text
    1. Carroll DN and
    2. Carroll DG
    (2009) Fatal intracranial bleed potentially due to a warfarin and influenza vaccine interaction. Ann Pharmacother 43:754760.
    OpenUrlCrossRefPubMed
    1. Fitzgerald M
    1. Cetin FH,
    2. Tunca H,
    3. Gney E, and
    4. Iseri E
    (2015) Neurotransmitter systems in autism spectrum disorder, in Autism Spectrum Disorder—Recent Advances (Fitzgerald M ed), InTech, London.
    1. Chang KC,
    2. Bell TD,
    3. Lauer BA, and
    4. Chai H
    (1978) Altered theophylline pharmacokinetics during acute respiratory viral illness. Lancet 1:11321133.
    OpenUrlPubMed
    1. Chen G,
    2. Wu D,
    3. Guo W,
    4. Cao Y,
    5. Huang D,
    6. Wang H,
    7. Wang T,
    8. Zhang X,
    9. Chen H,
    10. Yu H et al.
    (2020) Clinical and immunological features of severe and moderate coronavirus disease 2019. J Clin Invest 130:26202629.
    OpenUrlCrossRefPubMed
    1. Chippa V,
    2. Aleem A, and
    3. Anjum F
    (2022) Post Acute Coronavirus (COVID-19) Syndrome, StatPearls, Treasure Island, FL.
    1. Choutka J,
    2. Jansari V,
    3. Hornig M, and
    4. Iwasaki A
    (2022) Unexplained post-acute infection syndromes. Nat Med 28:911923.
    OpenUrlCrossRefPubMed
    1. Cleal JK,
    2. Lofthouse EM,
    3. Sengers BG, and
    4. Lewis RM
    (2018) A systems perspective on placental amino acid transport. J Physiol 596:55115522.
    OpenUrl
    1. Cojutti PG,
    2. Londero A,
    3. Della Siega P,
    4. Givone F,
    5. Fabris M,
    6. Biasizzo J,
    7. Tascini C, and
    8. Pea F
    (2020) Comparative population pharmacokinetics of darunavir in SARS-CoV-2 patients vs. HIV patients: the role of interleukin-6. Clin Pharmacokinet 59:12511260.
    OpenUrl
    1. Conway FM,
    2. Bloom CI, and
    3. Shah PL
    (2022) Susceptibility of patients with airways disease to SARS-CoV-2 infection. Am J Respir Crit Care Med 15:696703.
    OpenUrl
    1. Copur S,
    2. Berkkan M,
    3. Basile C,
    4. Tuttle K, and
    5. Kanbay M
    (2022) Post-acute COVID-19 syndrome and kidney diseases: what do we know? J Nephrol 35:795805.
    OpenUrl
    1. Cranshaw T and
    2. Harikumar T
    (2020) COVID-19 infection may cause clozapine intoxication: case report and discussion. Schizophr Bull 46:751.
    OpenUrl
    1. Croyle MA
    (2009) Long-term virus-induced alterations of CYP3A-mediated drug metabolism: a look at the virology, immunology and molecular biology of a multi-faceted problem. Expert Opin Drug Metab Toxicol 5:11891211.
    OpenUrlCrossRefPubMed
    1. Dallmann A,
    2. Liu XI,
    3. Burckart GJ, and
    4. van den Anker J
    (2019) Drug transporters expressed in the human placenta and models for studying maternal-fetal drug transfer. J Clin Pharmacol 59(Suppl 1):S70S81.
    OpenUrl
    1. de Jong LM,
    2. Jiskoot W,
    3. Swen JJ, and
    4. Manson ML
    (2020) Distinct effects of inflammation on cytochrome P450 regulation and drug metabolism: lessons from experimental models and a potential role for pharmacogenetics. Genes (Basel) 11:1509.
    OpenUrl
    1. Donato MT,
    2. Guillén MI,
    3. Jover R,
    4. Castell JV, and
    5. Gómez-Lechón MJ
    (1997) Nitric oxide-mediated inhibition of cytochrome P450 by interferon-gamma in human hepatocytes. J Pharmacol Exp Ther 281:484490.
    OpenUrlAbstract/FREE Full Text
    1. Edlow AG,
    2. Castro VM,
    3. Shook LL,
    4. Kaimal AJ, and
    5. Perlis RH
    (2022) Neurodevelopmental outcomes at 1 year in infants of mothers who tested positive for SARS-CoV-2 during pregnancy. JAMA Netw Open 5:e2215787.
    OpenUrl
    1. Eiermann B,
    2. Engel G,
    3. Johansson I,
    4. Zanger UM, and
    5. Bertilsson L
    (1997) The involvement of CYP1A2 and CYP3A4 in the metabolism of clozapine. Br J Clin Pharmacol 44:439446.
    OpenUrlCrossRefPubMed
    1. Evers R,
    2. Piquette-Miller M,
    3. Polli JW,
    4. Russel FGM,
    5. Sprowl JA,
    6. Tohyama K,
    7. de Wilt S,
    8. Xie W, and
    9. Brouwer K
    International Transporter Consortium (2018) Disease-associated changes in drug transporters may impact the pharmacokinetics and/or toxicity of drugs: a white paper from the International Transporter Consortium. Clin Pharmacol Ther 104:900915.
    OpenUrlCrossRefPubMed
    1. Gao Z,
    2. Xu Y,
    3. Sun C,
    4. Wang X,
    5. Guo Y,
    6. Qiu S, and
    7. Ma K
    (2021) A systematic review of asymptomatic infections with COVID-19. J Microbiol Immunol Infect 54:1216.
    OpenUrl
    1. García LF
    (2020) Immune response, inflammation, and the clinical spectrum of COVID-19. Front Immunol 11:1441.
    OpenUrlCrossRefPubMed
    1. Gęca T,
    2. Wojtowicz K,
    3. Guzik P, and
    4. Góra T
    (2022) Increased risk of COVID-19 in patients with diabetes mellitus—current challenges in pathophysiology, treatment and prevention. Int J Environ Res Public Health 19:6555.
    OpenUrl
    1. Gee S and
    2. Taylor D
    (2021) COVID-19 infection causes a reduction in neutrophil counts in patients taking clozapine. J Psychiatry Neurosci 46:E232E237.
    OpenUrl
    1. Geng Q,
    2. Tai W,
    3. Baxter VK,
    4. Shi J,
    5. Wan Y,
    6. Zhang X,
    7. Montgomery SA,
    8. Taft-Benz SA,
    9. Anderson EJ,
    10. Knight AC et al.
    (2021) Novel virus-like nanoparticle vaccine effectively protects animal model from SARS-CoV-2 infection. PLoS Pathog 17:e1009897.
    OpenUrl
    1. Giuliani F,
    2. Oros D,
    3. Gunier RB,
    4. Deantoni S,
    5. Rauch S,
    6. Casale R,
    7. Nieto R,
    8. Bertino E,
    9. Rego A,
    10. Menis C et al.
    (2022) Effects of prenatal exposure to maternal COVID-19 and perinatal care on neonatal outcome: results from the INTERCOVID Multinational Cohort Study. Am J Obstet Gynecol 227:488.e1488.e17.
    OpenUrl
    1. Gomolin IH,
    2. Chapron DJ, and
    3. Luhan PA
    (1985) Lack of effect of influenza vaccine on theophylline levels and warfarin anticoagulation in the elderly. J Am Geriatr Soc 33:269272.
    OpenUrlCrossRefPubMed
    1. Pai MP,
    2. Kiser JJ,
    3. Gubbins PO, and
    4. Rodvold KA
    1. Goralski KB,
    2. Ladda MA, and
    3. McNeil JO
    (2018) Drug-cytokine interactions, in Drug Interactions in Infectious Diseases: Mechanisms and Models of Drug Interactions (Pai MP, Kiser JJ, Gubbins PO, and Rodvold KA, eds) pp 163204, Springer International, Cham, Switzerland.
    1. Govind R,
    2. Fonseca de Freitas D,
    3. Pritchard M,
    4. Hayes RD, and
    5. MacCabe JH
    (2021) Clozapine treatment and risk of COVID-19 infection: retrospective cohort study. Br J Psychiatry 219:368374.
    OpenUrl
    1. Gregoire M,
    2. Le Turnier P,
    3. Gaborit BJ,
    4. Veyrac G,
    5. Lecomte R,
    6. Boutoille D,
    7. Canet E,
    8. Imbert BM,
    9. Bellouard R, and
    10. Raffi F
    (2020) Lopinavir pharmacokinetics in COVID-19 patients. J Antimicrob Chemother 75:27022704.
    OpenUrl
    1. Gurrera RJ,
    2. Gearin PF,
    3. Love J,
    4. Li KJ,
    5. Xu A,
    6. Donaghey FH, and
    7. Gerace MR
    (2022) Recognition and management of clozapine adverse effects: a systematic review and qualitative synthesis. Acta Psychiatr Scand 145:423441.
    OpenUrl
    1. Haddad FL,
    2. Patel SV, and
    3. Schmid S
    (2020) Maternal immune activation by poly I:C as a preclinical model for neurodevelopmental disorders: a focus on autism and schizophrenia. Neurosci Biobehav Rev 113:546556.
    OpenUrlCrossRefPubMed
    1. Harvey RJ and
    2. Yee BK
    (2013) Glycine transporters as novel therapeutic targets in schizophrenia, alcohol dependence and pain. Nat Rev Drug Discov 12:866885.
    OpenUrlCrossRefPubMed
    1. Healey Q,
    2. Sheikh A,
    3. Daines L, and
    4. Vasileiou E
    (2022) Symptoms and signs of long COVID: a rapid review and meta-analysis. J Glob Health 12:05014.
    OpenUrl
    1. Hervé C,
    2. Laupèze B,
    3. Del Giudice G,
    4. Didierlaurent AM, and
    5. Tavares Da Silva F
    (2019) The how’s and what’s of vaccine reactogenicity. NPJ Vaccines 4:39.
    OpenUrl
    1. Huang C,
    2. Wang Y,
    3. Li X,
    4. Ren L,
    5. Zhao J,
    6. Hu Y,
    7. Zhang L,
    8. Fan G,
    9. Xu J,
    10. Gu X et al.
    (2020) Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet 395:497506.
    OpenUrlCrossRefPubMed
    1. Hulo C,
    2. de Castro E,
    3. Masson P,
    4. Bougueleret L,
    5. Bairoch A,
    6. Xenarios I, and
    7. Le Mercier P
    (2011) ViralZone: a knowledge resource to understand virus diversity. Nucleic Acids Res 39:D576D582.
    OpenUrlCrossRefPubMed
    1. Jiang H-Y,
    2. Xu L-L,
    3. Shao L,
    4. Xia R-M,
    5. Yu Z-H,
    6. Ling Z-X,
    7. Yang F,
    8. Deng M, and
    9. Ruan B
    (2016) Maternal infection during pregnancy and risk of autism spectrum disorders: a systematic review and meta-analysis. Brain Behav Immun 58:165172.
    OpenUrlCrossRefPubMed
    1. Jonsson-Schmunk K,
    2. Ghose R, and
    3. Croyle MA
    (2021) Immunization and drug metabolizing enzymes: focus on hepatic cytochrome P450 3A. Expert Rev Vaccines 20:623634.
    OpenUrl
    1. Jonsson-Schmunk K,
    2. Wonganan P,
    3. Choi JH,
    4. Callahan SM, and
    5. Croyle MA
    (2016) Integrin receptors play a key role in the regulation of hepatic CYP3A. Drug Metab Dispos 44:758770.
    OpenUrlAbstract/FREE Full Text
    1. Kadry YA and
    2. Calderwood DA
    (2020) Chapter 22: Structural and signaling functions of integrins. Biochim Biophys Acta Biomembr 1862:183206.
    OpenUrlCrossRef
    1. Kakodkar P,
    2. Kaka N, and
    3. Baig MN
    (2020) A comprehensive literature review on the clinical presentation, and management of the pandemic coronavirus disease 2019 (COVID-19). Cureus 12:e7560.
    OpenUrl
    1. Kenigsberg TA,
    2. Hause AM,
    3. McNeil MM,
    4. Nelson JC,
    5. Ann Shoup J,
    6. Goddard K,
    7. Lou Y,
    8. Hanson KE,
    9. Glenn SC, and
    10. Weintraub ES
    (2022) Dashboard development for near real-time visualization of COVID-19 vaccine safety surveillance data in the Vaccine Safety Datalink. Vaccine 40:30643071.
    OpenUrl
    1. Klang E,
    2. Kassim G,
    3. Soffer S,
    4. Freeman R,
    5. Levin MA, and
    6. Reich DL
    (2020) Severe obesity as an independent risk factor for COVID-19 mortality in hospitalized patients younger than 50. Obesity (Silver Spring) 28:15951599.
    OpenUrl
    1. Kouhpayeh H and
    2. Ansari H
    (2022) Adverse events following COVID-19 vaccination: a systematic review and meta-analysis. Int Immunopharmacol 109:108906.
    OpenUrl
    1. Kraemer MJ,
    2. Furukawa CT,
    3. Koup JR,
    4. Shapiro GG,
    5. Pierson WE, and
    6. Bierman CW
    (1982) Altered theophylline clearance during an influenza B outbreak. Pediatrics 69:476480.
    OpenUrlPubMed
    1. Kurbat MN and
    2. Lelevich VV
    (2009) Metabolism of amino acids in the brain. Neurochem J 3:2328.
    OpenUrl
    1. La-Beck NM,
    2. Zamboni BA,
    3. Gabizon A,
    4. Schmeeda H,
    5. Amantea M,
    6. Gehrig PA, and
    7. Zamboni WC
    (2012) Factors affecting the pharmacokinetics of pegylated liposomal doxorubicin in patients. Cancer Chemother Pharmacol 69:4350.
    OpenUrlCrossRefPubMed
    1. Lager S and
    2. Powell TL
    (2012) Regulation of nutrient transport across the placenta. J Pregnancy 2012:179827.
    OpenUrlCrossRefPubMed
    1. Lamers MM and
    2. Haagmans BL
    (2022) SARS-CoV-2 pathogenesis. Nat Rev Microbiol 20:270284.
    OpenUrlCrossRef
    1. Lau O and
    2. Vadlamudi NK
    (2022) Immunogenicity and safety of the COVID-19 vaccines compared with control in healthy adults: a qualitative and systematic review. Value Health 25:717730.
    OpenUrl
    1. Le HT,
    2. Boquet MP,
    3. Clark EA,
    4. Callahan SM, and
    5. Croyle MA
    (2006) Renal pathophysiology after systemic administration of recombinant adenovirus: changes in renal cytochromes P450 based on vector dose. Hum Gene Ther 17:10951111.
    OpenUrlPubMed
    1. Lee GC,
    2. Restrepo MI,
    3. Harper N,
    4. Manoharan MS,
    5. Smith AM,
    6. Meunier JA,
    7. Sanchez-Reilly S,
    8. Ehsan A,
    9. Branum AP,
    10. Winter C et al.
    (2021) Immunologic resilience and COVID-19 survival advantage. J Allergy Clin Immunol 148:11761191.
    OpenUrl
    1. Leist SR,
    2. Dinnon KH 3rd.,
    3. Schäfer A,
    4. Tse LV,
    5. Okuda K,
    6. Hou YJ,
    7. West A,
    8. Edwards CE,
    9. Sanders W,
    10. Fritch EJ et al.
    (2020) A mouse-adapted SARS-CoV-2 induces acute lung injury and mortality in standard laboratory mice. Cell 183:10701085.e12.
    OpenUrlCrossRefPubMed
    1. Lenoir C,
    2. Daali Y,
    3. Rollason V,
    4. Curtin F,
    5. Gloor Y,
    6. Bosilkovska M,
    7. Walder B,
    8. Gabay C,
    9. Nissen MJ,
    10. Desmeules JA et al.
    (2021) Impact of acute inflammation on cytochromes P450 activity assessed by the Geneva cocktail. Clin Pharmacol Ther 109:16681676.
    OpenUrl
    1. Lenoir C,
    2. Rodieux F,
    3. Desmeules JA,
    4. Rollason V, and
    5. Samer CF
    (2021) Impact of inflammation on cytochromes P450 activity in pediatrics: a systematic review. Clin Pharmacokinet 60:15371555.
    OpenUrl
    1. Lenoir C,
    2. Rollason V,
    3. Desmeules JA, and
    4. Samer CF
    (2021) Influence of inflammation on cytochromes P450 activity in adults: a systematic review of the literature. Front Pharmacol 12:733935.
    OpenUrl
    1. Lenoir C,
    2. Terrier J,
    3. Gloor Y,
    4. Curtin F,
    5. Rollason V,
    6. Desmeules JA,
    7. Daali Y,
    8. Reny JL, and
    9. Samer CF
    (2021) Impact of SARS-CoV-2 infection (COVID-19) on cytochromes P450 activity assessed by the Geneva cocktail. Clin Pharmacol Ther 110:13581367.
    OpenUrl
    1. Lewis DA,
    2. Hashimoto T, and
    3. Volk DW
    (2005) Cortical inhibitory neurons and schizophrenia. Nat Rev Neurosci 6:312324.
    OpenUrlCrossRefPubMed
    1. Liu J,
    2. Lu F,
    3. Chen Y,
    4. Plow E, and
    5. Qin J
    (2022) Integrin mediates cell entry of the SARS-CoV-2 virus independent of cellular receptor ACE2. J Biol Chem 298:101710.
    OpenUrl
    1. Lucas AT,
    2. Herity LB,
    3. Kornblum ZA,
    4. Madden AJ,
    5. Gabizon A,
    6. Kabanov AV,
    7. Ajamie RT,
    8. Bender DM,
    9. Kulanthaivel P,
    10. Sanchez-Felix MV et al.
    (2017) Pharmacokinetic and screening studies of the interaction between mononuclear phagocyte system and nanoparticle formulations and colloid forming drugs. Int J Pharm 526:443454.
    OpenUrl
    1. Lucas AT,
    2. Madden AJ, and
    3. Zamboni WC
    (2015) Formulation and physiologic factors affecting the pharmacology of carrier-mediated anticancer agents. Expert Opin Drug Metab Toxicol 11:14191433.
    OpenUrlCrossRefPubMed
    1. Lucas AT,
    2. Price LSL,
    3. Schorzman AN,
    4. Storrie M,
    5. Piscitelli JA,
    6. Razo J, and
    7. Zamboni WC
    (2018) Factors affecting the pharmacology of antibody-drug conjugates. Antibodies (Basel) 7:10.
    OpenUrl
    1. Madden AJ,
    2. Oberhardt B,
    3. Lockney D,
    4. Santos C,
    5. Vennam P,
    6. Arney D,
    7. Franzen S,
    8. Lommel SA,
    9. Miller CR,
    10. Gehrig P et al.
    (2017) Pharmacokinetics and efficacy of doxorubicin-loaded plant virus nanoparticles in preclinical models of cancer. Nanomedicine (Lond) 12:25192532.
    OpenUrl
    1. Marzolini C,
    2. Stader F,
    3. Stoeckle M,
    4. Franzeck F,
    5. Egli A,
    6. Bassetti S,
    7. Hollinger A,
    8. Osthoff M,
    9. Weisser M,
    10. Gebhard CE et al.
    (2020) Effect of systemic inflammatory response to SARS-CoV-2 on lopinavir and hydroxychloroquine plasma concentrations. Antimicrob Agents Chemother 64:e01177-20.
    OpenUrlAbstract/FREE Full Text
    1. Mathieu E,
    2. Ritchie H,
    3. Ortiz-Ospina E,
    4. Roser M,
    5. Hasell J,
    6. Appel C,
    7. Giattino C, and
    8. Rodés-Guirao L
    (2021) A global database of COVID-19 vaccinations. Nat Hum Behav 5:947953.
    OpenUrl
    1. McColl ER and
    2. Piquette-Miller M
    (2019) Poly(I:C) alters placental and fetal brain amino acid transport in a rat model of maternal immune activation. Am J Reprod Immunol 81:e13115.
    OpenUrl
    1. McColl ER and
    2. Piquette-Miller M
    (2022) Infection during pregnancy downregulates the expression of amino acid transporters in rat and human placentas, in American Society for Pharmacology and Experimental Therapeutics Annual Meeting at Experimental Biology, 2022 April 2–5; Philadelphia, PA.
    1. McDonald JW and
    2. Johnston MV
    (1990) Physiological and pathophysiological roles of excitatory amino acids during central nervous system development. Brain Res Brain Res Rev 15:4170.
    OpenUrlCrossRefPubMed
    1. Medzhitov R
    (2010) Inflammation 2010: new adventures of an old flame. Cell 140:771776.
    OpenUrlCrossRefPubMed
    1. Meo SA,
    2. Bukhari IA,
    3. Akram J,
    4. Meo AS, and
    5. Klonoff DC
    (2021) COVID-19 vaccines: comparison of biological, pharmacological characteristics and adverse effects of Pfizer/BioNTech and Moderna vaccines. Eur Rev Med Pharmacol Sci 25:16631669.
    OpenUrlPubMed
    1. Meredith CG,
    2. Christian CD,
    3. Johnson RF,
    4. Troxell R,
    5. Davis GL, and
    6. Schenker S
    (1985) Effects of influenza virus vaccine on hepatic drug metabolism. Clin Pharmacol Ther 37:396401.
    OpenUrlPubMed
    1. Mohseni Afshar Z,
    2. Barary M,
    3. Hosseinzadeh R,
    4. Alijanpour A,
    5. Hosseinzadeh D,
    6. Ebrahimpour S,
    7. Nazary K,
    8. Sio TT,
    9. Sullman MJM,
    10. Carson-Chahhoud K et al.
    (2022) Breakthrough SARS-CoV-2 infections after vaccination: a critical review. Hum Vaccin Immunother 18:2051412.
    OpenUrl
    1. Morgan ET,
    2. Skubic C,
    3. Lee CM,
    4. Cokan KB, and
    5. Rozman D
    (2020) Regulation of cytochrome P450 enzyme activity and expression by nitric oxide in the context of inflammatory disease. Drug Metab Rev 52:455471.
    OpenUrl
    1. Nalbandian A,
    2. Sehgal K,
    3. Gupta A,
    4. Madhavan MV,
    5. McGroder C,
    6. Stevens JS,
    7. Cook JR,
    8. Nordvig AS,
    9. Shalev D,
    10. Sehrawat TS et al.
    (2021) Post-acute COVID-19 syndrome. Nat Med 27:601615.
    OpenUrlCrossRefPubMed
    1. Negi N,
    2. Maurya SP,
    3. Singh R, and
    4. Das BK
    (2022) An update on host immunity correlates and prospects of re-infection in COVID-19. Int Rev Immunol 41:367392.
    OpenUrl
    1. Nguyen YTK,
    2. Ha HTT,
    3. Nguyen TH, and
    4. Nguyen LN
    (2021) The role of SLC transporters for brain health and disease. Cell Mol Life Sci 79:20.
    OpenUrl
    1. Ohlis A,
    2. Sörberg Wallin A,
    3. Sarafis A,
    4. Sjöqvist H,
    5. MacCabe JH,
    6. Ahlen J, and
    7. Dalman C
    (2022) Clozapine treatment and risk of severe COVID-19 infection. Acta Psychiatr Scand 145:7985.
    OpenUrl
    1. Padín-González E,
    2. Lancaster P,
    3. Bottini M,
    4. Gasco P,
    5. Tran L,
    6. Fadeel B,
    7. Wilkins T, and
    8. Monopoli MP
    (2022) Understanding the role and impact of poly (ethylene glycol) (PEG) on nanoparticle formulation: implications for COVID-19 vaccines. Front Bioeng Biotechnol 10:882363.
    OpenUrl
    1. Papadopoulos V,
    2. Li L, and
    3. Samplaski M
    (2021) Why does COVID-19 kill more elderly men than women? Is there a role for testosterone? Andrology 9:6572.
    OpenUrl
    1. Lee D-H,
    2. Schaffer SW, and
    3. Park Ea
    1. Park E,
    2. Cohen I,
    3. Gonzalez M,
    4. Vastellano MR,
    5. Flory M,
    6. Jenkins EC,
    7. Brown T, and
    8. Schuller-Levis G
    (2017) Is taurine a biomarker in autistic spectrum disorder? in Taurine 10 (Lee D-H, Schaffer SW, and Park Ea, eds) pp 316, Springer, Dordrecht, The Netherlands
    1. Peng M,
    2. He J,
    3. Xue Y,
    4. Yang X,
    5. Liu S, and
    6. Gong Z
    (2021) Role of hypertension on the severity of COVID-19: a review. J Cardiovasc Pharmacol 78:e648e655.
    OpenUrlCrossRef
    1. Petrovic V and
    2. Piquette-Miller M
    (2010) Impact of polyinosinic/polycytidylic acid on placental and hepatobiliary drug transporters in pregnant rats. Drug Metab Dispos 38:17601766.
    OpenUrlAbstract/FREE Full Text
    1. Petrovic V and
    2. Piquette-Miller M
    (2015) Polyinosinic/polycytidylic acid-mediated changes in maternal and fetal disposition of lopinavir in rats. Drug Metab Dispos 43:951957.
    OpenUrlAbstract/FREE Full Text
    1. Place VA,
    2. Pyle MM, and
    3. De la Huerga J
    (1969) Ethambutol in tuberculous meningitis. Am Rev Respir Dis 99:783785.
    OpenUrlPubMed
    1. Ponsford M,
    2. Castle D,
    3. Tahir T,
    4. Robinson R,
    5. Wade W,
    6. Steven R,
    7. Bramhall K,
    8. Moody M,
    9. Carne E,
    10. Ford C et al.
    (2018) Clozapine is associated with secondary antibody deficiency. Br J Psychiatry 214:17.
    OpenUrl
    1. Ponsford MJ,
    2. Pecoraro A, and
    3. Jolles S
    (2019) Clozapine-associated secondary antibody deficiency. Curr Opin Allergy Clin Immunol 19:553562.
    OpenUrl
    1. Raaska K,
    2. Raitasuo V, and
    3. Neuvonen PJ
    (2001) Effect of influenza vaccination on serum clozapine and its main metabolite concentrations in patients with schizophrenia. Eur J Clin Pharmacol 57:705708.
    OpenUrlPubMed
    1. Rahman S,
    2. Montero MTV,
    3. Rowe K,
    4. Kirton R, and
    5. Kunik Jr F
    (2021) Epidemiology, pathogenesis, clinical presentations, diagnosis and treatment of COVID-19: a review of current evidence. Expert Rev Clin Pharmacol 14:601621.
    OpenUrl
    1. Ramakrishnan RK,
    2. Kashour T,
    3. Hamid Q,
    4. Halwani R, and
    5. Tleyjeh IM
    (2021) Unraveling the mystery surrounding post-acute sequelae of COVID-19. Front Immunol 12:686029.
    OpenUrlCrossRefPubMed
    1. Renton KW
    (2005) Regulation of drug metabolism and disposition during inflammation and infection. Expert Opin Drug Metab Toxicol 1:629640.
    OpenUrlCrossRefPubMed
    1. Renton KW and
    2. Mannering GJ
    (1976a) Depression of hepatic cytochrome P-450-dependent monooxygenase systems with administered interferon inducing agents. Biochem Biophys Res Commun 73:343348.
    OpenUrlCrossRefPubMed
    1. Renton KW and
    2. Mannering GJ
    (1976b) Depression of the hepatic cytochrome P-450 mono-oxygenase system by administered tilorone (2,7-bis(2-(diethylamino)ethoxy)fluoren-9-one dihydrochloride). Drug Metab Dispos 4:223231.
    OpenUrlAbstract
    1. Robertson WC Jr.
    (2002) Carbamazepine toxicity after influenza vaccination. Pediatr Neurol 26:6163.
    OpenUrlPubMed
    1. Rodrigues TS,
    2. de Sá KSG,
    3. Ishimoto AY,
    4. Becerra A,
    5. Oliveira S,
    6. Almeida L,
    7. Gonçalves AV,
    8. Perucello DB,
    9. Andrade WA,
    10. Castro R et al.
    (2021) Inflammasomes are activated in response to SARS-CoV-2 infection and are associated with COVID-19 severity in patients. J Exp Med 218:20201707.
    OpenUrl
    1. Røge R,
    2. Møller BK,
    3. Andersen CR,
    4. Correll CU, and
    5. Nielsen J
    (2012) Immunomodulatory effects of clozapine and their clinical implications: what have we learned so far? Schizophr Res 140:204213.
    OpenUrlCrossRefPubMed
    1. Safadi MAP,
    2. Spinardi J,
    3. Swerdlow D, and
    4. Srivastava A
    (2022) COVID-19 disease and vaccination in pregnant and lactating women. Am J Reprod Immunol 88:e13550.
    OpenUrl
    1. Sahin U,
    2. Muik A,
    3. Derhovanessian E,
    4. Vogler I,
    5. Kranz LM,
    6. Vormehr M,
    7. Baum A,
    8. Pascal K,
    9. Quandt J,
    10. Maurus D et al.
    (2020) COVID-19 vaccine BNT162b1 elicits human antibody and TH1 T cell responses. Nature 586:594599.
    OpenUrlPubMed
    1. Saleem S,
    2. Shaukat F,
    3. Gul A,
    4. Arooj M, and
    5. Malik A
    (2017) Potential role of amino acids in pathogenesis of schizophrenia. Int J Health Sci (Qassim) 11:6368.
    OpenUrl
    1. Schoergenhofer C,
    2. Jilma B,
    3. Stimpfl T,
    4. Karolyi M, and
    5. Zoufaly A
    (2020) Pharmacokinetics of lopinavir and ritonavir in patients hospitalized with coronavirus disease 2019 (COVID-19). Ann Intern Med 173:670672.
    OpenUrl
    1. Simons P,
    2. Rinaldi DA,
    3. Bondu V,
    4. Kell AM,
    5. Bradfute S,
    6. Lidke DS, and
    7. Buranda T
    (2021) Integrin activation is an essential component of SARS-CoV-2 infection. Sci Rep 11:20398.
    OpenUrlCrossRef
    1. Sippel JE,
    2. Mikhail IA,
    3. Girgis NI, and
    4. Youssef HH
    (1974) Rifampin concentrations in cerebrospinal fluid of patients with tuberculous meningitis. Am Rev Respir Dis 109:579580.
    OpenUrlPubMed
    1. Siskind D,
    2. Honer WG,
    3. Clark S,
    4. Correll CU,
    5. Hasan A,
    6. Howes O,
    7. Kane JM,
    8. Kelly DL,
    9. Laitman R,
    10. Lee J et al.
    (2020) Consensus statement on the use of clozapine during the COVID-19 pandemic. J Psychiatry Neurosci 45:222223.
    OpenUrlPubMed
    1. Soontornpun A,
    2. Manoyana N,
    3. Apaijai N,
    4. Pinyopornpanish K,
    5. Pinyopornpanish K,
    6. Nadsasarn A,
    7. Tanprawate S,
    8. Chattipakorn N, and
    9. Chattipakorn SC
    (2020) Influenza immunization does not predominantly alter levels of phenytoin, and cytochrome P-450 enzymes in epileptic patients receiving phenytoin monotherapy. Epilepsy Res 167:106471.
    OpenUrl
    1. Sørensen HJ,
    2. Mortensen EL,
    3. Reinisch JM, and
    4. Mednick SA
    (2009) Association between prenatal exposure to bacterial infection and risk of schizophrenia. Schizophr Bull 35:631637.
    OpenUrlCrossRefPubMed
    1. Soriano JB,
    2. Murthy S,
    3. Marshall JC,
    4. Relan P, and
    5. Diaz JV;
    WHO Clinical Case Definition Working Group on Post-COVID-19 Condition (2022) A clinical case definition of post-COVID-19 condition by a Delphi consensus. Lancet Infect Dis 22:e102e107.
    OpenUrlCrossRefPubMed
    1. Sproston NR and
    2. Ashworth JJ
    (2018) Role of C-reactive protein at sites of inflammation and infection. Front Immunol 9:754.
    OpenUrlCrossRefPubMed
    1. Stanke-Labesque F,
    2. Gautier-Veyret E,
    3. Chhun S, and
    4. Guilhaumou R;
    French Society of Pharmacology and Therapeutics (2020) Inflammation is a major regulator of drug metabolizing enzymes and transporters: consequences for the personalization of drug treatment. Pharmacol Ther 215:107627.
    OpenUrl
    1. Stults BM and
    2. Hashisaki PA
    (1983) Influenza vaccination and theophylline pharmacokinetics in patients with chronic obstructive lung disease. West J Med 139:651654.
    OpenUrlPubMed
    1. Szebeni J,
    2. Storm G,
    3. Ljubimova JY,
    4. Castells M,
    5. Phillips EJ,
    6. Turjeman K,
    7. Barenholz Y,
    8. Crommelin DJA, and
    9. Dobrovolskaia MA
    (2022) Applying lessons learned from nanomedicines to understand rare hypersensitivity reactions to mRNA-based SARS-CoV-2 vaccines. Nat Nanotechnol 17:337346.
    OpenUrl
    1. Tabatabaie L,
    2. Klomp LW,
    3. Berger R, and
    4. de Koning TJ
    (2010) L-serine synthesis in the central nervous system: a review on serine deficiency disorders. Mol Genet Metab 99:256262.
    OpenUrlCrossRefPubMed
    1. Tahtinen S,
    2. Tong AJ,
    3. Himmels P,
    4. Oh J,
    5. Paler-Martinez A,
    6. Kim L,
    7. Wichner S,
    8. Oei Y,
    9. McCarron MJ,
    10. Freund EC et al.
    (2022) IL-1 and IL-1ra are key regulators of the inflammatory response to RNA vaccines. Nat Immunol 23:532542.
    OpenUrlCrossRef
    1. Takeuchi O and
    2. Akira S
    (2009) Innate immunity to virus infection. Immunol Rev 227:7586.
    OpenUrlCrossRefPubMed
    1. Thompson D,
    2. Delorme CM,
    3. White RF, and
    4. Honer WG
    (2021) Elevated clozapine levels and toxic effects after SARS-CoV-2 vaccination. J Psychiatry Neurosci 46:E210E211.
    OpenUrl
    1. Tio N,
    2. Schulte PFJ, and
    3. Martens HJM
    (2021) Clozapine intoxication in COVID-19. Am J Psychiatry 178:123127.
    OpenUrl
    1. Tiwari S,
    2. Goel G, and
    3. Kumar A
    (2022) Natural and genetically modified animal models to investigate pulmonary and extrapulmonary manifestations of COVID-19. Int Rev Immunol DOI: 10.1080/08830185.2022.2089666[published ahead of print].
    1. Lee D-H,
    2. Schaffer SW, and
    3. Park Ea
    1. Tochitani S
    (2017) Functions of maternally derived taurine in fetal and neonatal brain development, in Taurine 10 (Lee D-H, Schaffer SW, and Park Ea, eds) pp 1726, Springer, Dordrecht, The Netherlands.
    1. Touyz RM,
    2. Boyd MOE,
    3. Guzik T,
    4. Padmanabhan S,
    5. McCallum L,
    6. Delles C,
    7. Mark PB,
    8. Petrie JR,
    9. Rios F,
    10. Montezano AC et al.
    (2021) Cardiovascular and renal risk factors and complications associated with COVID-19. CJC Open 3:12571272.
    OpenUrl
    1. Veerman SRT,
    2. Moscou T,
    3. Bogers JPAM,
    4. Cohen D, and
    5. Schulte PFJ
    (2022) Clozapine and COVID-19 vaccination: effects on blood levels and leukocytes. An observational cohort study. Acta Psychiatr Scand 146:168178.
    OpenUrl
    1. Wagner E,
    2. Siafis S,
    3. Fernando P,
    4. Falkai P,
    5. Honer WG,
    6. Röh A,
    7. Siskind D,
    8. Leucht S, and
    9. Hasan A
    (2021) Efficacy and safety of clozapine in psychotic disorders—a systematic quantitative meta-review. Transl Psychiatry 11:487.
    OpenUrl
    1. Wu J,
    2. Li J,
    3. Zhu G,
    4. Zhang Y,
    5. Bi Z,
    6. Yu Y,
    7. Huang B,
    8. Fu S,
    9. Tan Y,
    10. Sun J et al.
    (2020) Clinical features of maintenance hemodialysis patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China. Clin J Am Soc Nephrol 15:11391145.
    OpenUrlAbstract/FREE Full Text
    1. Yahyaoui R and
    2. Pérez-Frías J
    (2019) Amino acid transport defects in human inherited metabolic disorders. Int J Mol Sci 21:119.
    OpenUrl
    1. Yin SW,
    2. Zhou Z,
    3. Wang JL,
    4. Deng YF,
    5. Jing H, and
    6. Qiu Y
    (2021) Viral loads, lymphocyte subsets and cytokines in asymptomatic, mildly and critical symptomatic patients with SARS-CoV-2 infection: a retrospective study. Virol J 18:126.
    OpenUrl
    1. Zamboni WC,
    2. Strychor S,
    3. Maruca L,
    4. Ramalingam S,
    5. Zamboni BA,
    6. Wu H,
    7. Friedland DM,
    8. Edwards RP,
    9. Stoller RG,
    10. Belani CP et al.
    (2009) Pharmacokinetic study of pegylated liposomal CKD-602 (S-CKD602) in patients with advanced malignancies. Clin Pharmacol Ther 86:519526.
    OpenUrlCrossRefPubMed
    1. Zaragoz R
    (2020) Transport of amino acids across the blood-brain barrier. Front Physiol 11:973.
    OpenUrl
    1. Zimmer K
    (2020) Why some COVID-19 cases are worse than others, The Scientist. https://www.the-scientist.com/news-opinion/why-some-covid-19-cases-are-worse-than-others-67160.
Back to top

In this issue

Download PDF
Article Alerts
Email Article
Citation Tools

Research Article50th Anniversary Celebration Collection—Minireview

COVID-19 Infection and Vaccine Impacts on Drug Metabolism

Eliza R. McColl, Maria A. Croyle, William C. Zamboni, William G. Honer, Mark Heise, Micheline Piquette-Miller and Kerry B. Goralski
Drug Metabolism and Disposition January 1, 2023, 51 (1) 130-141; DOI: https://doi.org/10.1124/dmd.122.000934
del.icio.us logo Digg logo Reddit logo Twitter logo Facebook logo Google logo Mendeley logo

Jump to section

Advertisement