Antivirals With Activity Against Mpox: A Clinically Oriented Review

Abstract

Mpox virus is an emergent human pathogen. While it is less lethal than smallpox, it can still cause significant morbidity and mortality. In this review, we explore 3 antiviral agents with activity against mpox and other orthopoxviruses: cidofovir, brincidofovir, and tecovirimat. Cidofovir, and its prodrug brincidofovir, are inhibitors of DNA replication with a broad spectrum of activity against multiple families of double-stranded DNA viruses. Tecovirimat has more specific activity against orthopoxviruses and inhibits the formation of the extracellular enveloped virus necessary for cell-to-cell transmission. For each agent, we review basic pharmacology, data from animal models, and reported experience in human patients.

Human mpox, caused by the mpox virus, a member of the genus Orthopoxvirus within the Poxviridae family of double-stranded DNA (dsDNA) viruses (Figure 1) [1–4], was first described in a 9-month-old infant in the Democratic Republic of Congo in 1970 [5]. Since then, it has resulted in multiple outbreaks in Central and West Africa, and occasionally in Europe and North America [6], most notably 47 human cases in the US Midwest in 2003 [7]. This outbreak was attributed to prairie dogs that became infected though contact with rodents imported from Ghana [8]. Human infections in endemic areas have been described in association with close contact with infected animals through hunting and skinning, or household rodent infestation [9]. Human-to-human transmission has also been described in household contacts of index cases, particularly among those who are unvaccinated against smallpox [10]. Proposed routes of transmission include salivary or respiratory secretions; contact with skin lesions, body fluids, or contaminated fomites; and possibly fecal shedding [10–12]. It is estimated that smallpox vaccination provides 85% protection against mpox, explaining the increase in susceptible hosts since smallpox eradication and discontinuation of routine smallpox vaccination [13]. The clinical course and possible complications of human mpox are illustrated in Figure 2 [9, 14–16]. Genomic sequencing of mpox isolates from the United States, West Africa, and Central Africa demonstrated the existence of 2 clades: the Congo Basin (CB) clade and the West African (WA) clade, including the 2003 US samples [17]. The CB clade is associated with increased human-to-human transmission, more pronounced rash, viremia, severe illness, and a higher case fatality rate (10.6% vs 3.6%) compared with the WA clade [6, 17]. Diagnosis is made by combining the clinical and epidemiological picture with a viral assay, most commonly a viral DNA detection assay by real-time polymerase chain reaction [18]. The optimal specimen is a lesion exudate or crust material. Infections can be diagnosed retrospectively with serological testing [19]. For years, the management of mpox infections has relied on supportive care and management of complications; however, the recent development of new antivirals, such as tecovirimat and brincidofovir, has opened new therapeutic opportunities [20].

As of 17 June 2022, 2525 confirmed cases of mpox have been reported from 37 countries not known to be endemic for mpox. The highest number of cases have been described in the United Kingdom, Spain, and Germany [21]. Preliminary data suggest the ongoing outbreak is related to the WA clade. A particular clinical manifestation reported is the initial appearance of the rash in the genital or perianal area, suggesting close physical contact as the route of transmission [22]. In light of this unprecedented outbreak, this review aims to provide a clinically oriented discussion of 3 antiviral agents with known activity against mpox: cidofovir (CDV), brincidofovir (BCV), and tecovirimat.

CIDOFOVIR

Basic Pharmacology

Although CDV (Vistide, Gilead) has broad activity against many DNA viruses including orthopoxviruses, it is only Food and Drug Administration (FDA) approved for the treatment of cytomegalovirus retinitis [23, 24]. Cidofovir is a prodrug, which must first enter host cells, then is phosphorylated by cellular enzymes into the active form, CDV diphosphate (CDV-pp) [24]. Once phosphorylated, CDV-pp has a prolonged intracellular half-life [25, 26]. During DNA replication, CDV-pp is incorporated into the growing DNA strand and slows synthesis of DNA (Figure 3). Cidofovir diphosphate may also inhibit DNA polymerase 3′–5′ exonuclease activity [24].

Resistance to CDV has been well described. Using serial passage with increasing CDV concentrations, resistant poxviruses can be selected in vitro [27]. These mutations appear to be similar in mpox and vaccinia virus and are due to point mutations in the conserved poxvirus DNA polymerase 3′–5′ exonuclease and the DNA polymerase catalytic domains [27, 28]. Resistance to CDV typically occurs in a stepwise fashion, with moderate resistance occurring with single mutations and higher levels of resistance occurring with multiple mutations [27]. Studies have demonstrated that CDV-resistant virus is significantly less virulent than wild-type strains, as challenges with wild-type virus were commonly lethal, while CDV-resistant virus caused a mild disease course. These data indicate that CDV resistance is slow to develop and is associated with a fitness cost for orthopoxviruses [27, 29].

Pharmacokinetic Data

Cidofovir is poorly absorbed orally and only available by intravenous infusion. Plasma CDV is rapidly renally filtered and secreted, whereas intracellular phosphorylated metabolites have a prolonged half-life, which allows for weekly or biweekly dosing (Table 1) [30, 31].

Animal Data

Various animal models have evaluated the efficacy of CDV for the treatment of multiple orthopoxvirus infections, including cowpox, vaccinia, mpox, and ectromelia (mousepox) viruses [32]. The majority of these studies evaluated the use of CDV at the time of orthopoxvirus exposure or soon (24–48 hours) thereafter, and it is unclear how time to treatment in these models correlates with the timeline of human infection. Nevertheless, in mice infected with vaccinia and cowpox viruses, intraperitoneal CDV prevented mortality when given up to 96 hours after infection, a time point almost halfway through the disease course in this animal model. Cidofovir reduced viral titers in the lungs, liver, kidney, and spleen [33] in a T-cell–deficient murine model of progressive vaccinia. Topical CDV prevented disease progression when given within 2 days of infection and decreased lesion severity up to 5 days postinfection, while systemic CDV decreased lesion severity when administered up to 15 days postinfection [34]. Further, in mice infected with cowpox virus, CDV has been shown to not only decrease viral loads but also to decrease cytokine levels in plasma and tissue, including interleukin (IL)-2, IL-3, IL-6, and IL-10 [35]. It is unclear if CDV has immunomodulatory effects or if these results are due to reduced viral titers.

In cynomolgus monkeys vaccinated with vaccinia virus, systemic CDV reduced the size of lesions at the vaccine site and promoted more rapid healing of the initial lesion [36]. In nonhuman primates exposed to mpox, CDV has been shown to prevent lesion development when given up to 48 hours after infection, while monkeys treated with placebo had numerous lesions and viremia [37]. Taken together, systemic CDV appears to be most effective when given early after mpox exposure, but may be useful at decreasing disease manifestations even when given relatively late in the mpox disease course.

Toxicity

Cidofovir is associated with dose-limiting nephrotoxicity, which is characterized by proteinuria followed by glucosuria, decreased bicarbonate, uric acid, and phosphate. If CDV is continued, this leads to serum creatinine elevation, which can be severe [31–33]. Nephrotoxicity due to CDV is dose-related [32] and is due to accumulation of CDV in kidney proximal tubule cells through organic anion transporter 1 (OAT1) [34]. Nephrotoxicity can be partially ameliorated by probenecid, which is an inhibitor of OAT1 transport and reduces CDV accumulation in proximal tubular cells [34]. In phase I/II studies in patients with AIDS, pre-hydration and probenecid reduced rates of nephrotoxicity, especially at CDV doses greater than 3 mg/kg (Table 1) [36]. Due to this nephrotoxicity, CDV is contraindicated in patients with serum creatinine greater than 1.5 mg/dL, creatinine clearance of 55 mL/minute or less, or 2+ or greater proteinuria, and it is recommended to avoid concomitant nephrotoxic medications [33].

Clinical Data in Humans

In humans, CDV has been used to treat cases of infection with poxviruses. The activity of the intravenous (IV) formulation was documented in patients with molluscum contagiosum receiving CDV for a concomitant AIDS-associated cytomegalovirus (CMV) retinitis, with subsequent resolution of molluscum lesions [38]. Additional case reports mention the use of IV CDV as part of a multipronged management approach for ocular cowpox [39, 40]. It has also been used in 1 patient with eczema vaccinatum in combination with tecovirimat [41]. Topical CDV has been successfully used to treat children and adults with molluscum contagiosum or orf. The strengths of the compounded creams varied from 1% to 3%, and the used vehicles differed, although vehicles containing propylene glycol were preferred, given that propylene glycol can enhance the bioavailability of CDV [42–44]. The lesions typically demonstrate acute inflammation after application of CDV, followed by dramatic resolution [45]. In some patients, the lesions recurred after discontinuation of topical CDV; however, they were successfully managed with either an additional course of topical CDV [43] or curettage [44]. In 1 patient with recalcitrant molluscum contagiosum, 1% CDV was injected into skin lesions with a 0.05-mL volume per lesion, with complete remission of the treated lesions without scarring, and with the antiviral activity being limited to the treated skin lesions [46].

BRINCIDOFOVIR

Basic Pharmacology

Brincidofovir is a lipid-conjugated CDV analogue that is marketed under the brand name Tembexa (Chimerix). Brincidofovir was FDA-approved in 2021 for the treatment of smallpox [47]. Like CDV, BCV has broad activity against dsDNA viruses but has lower half-maximal effective concentration (EC₅₀) than CDV against many dsDNA viruses, including adenoviruses, herpesviruses, and orthopoxviruses (Table 1) [46–50]. The added alkoxyalkyl moiety in BCV is structurally similar to lysophosphatidylcholine (LPC), which allows BCV to be taken up by the small intestines [25]. Contrary to CDV, which slowly crosses cellular membranes, BCV readily enters host cells due to its lipophilicity [25]. Brincidofovir is then hydrolyzed by cellular phospholipases into CDV [25] and phosphorylated into CDV-pp. Cidofovir diphosphate reaches higher intracellular concentrations after BCV administration due to its ability to cross cellular membranes more efficiently. Like CDV, BCV has a prolonged intracellular half-life and inhibits poxviruses DNA replication (Figure 3) [25, 26]. As BCV is converted into CDV, cross-resistance between BCV and CDV is expected.

Pharmacokinetic Data

Initial studies in humans have shown that oral BCV is absorbed in the fasting state and has lower peak CDV concentrations in plasma [51]. This gives BCV the convenience of oral dosing (Table 1). In addition, BCV demonstrated a significantly higher penetration into lung, spleen, and liver tissues, albeit with lower concentrations in the kidneys [52]. Unlike CDV, which is transported into the proximal convoluted tubules by OAT1, where it accumulates and causes renal damage, BCV is not a substrate for OAT1 [52, 53]. Thus, BCV does not accumulate in the kidneys and has a lower risk for nephrotoxicity [52, 53].

Animal Data

Brincidofovir has been tried in multiple poxvirus animal models [54–57]. In mice infected with ectromelia virus, CDV and BCV reduced mortality significantly compared with placebo [54]. Furthermore, BCV prevented mortality when given within 5 days of intranasal ectromelia virus challenge, which is thought to be analogous to the time of first lesion appearance in mpox [54]. In a rabbitpox model in which therapy was initiated on the first day of lesion appearance, rabbits treated at day 3 postinfection had improved survival (88%) compared with those treated at day 4 (67%) [55]. There was no statistical improvement from placebo if given later than day 4, regardless of when lesions occurred [55]. Similarly, an intradermal rabbitpox model showed BCV improved survival when started immediately at the time of fever (around day 2 postinfection) or within 24 to 48 hours with 100% versus 93% survival, respectively [56].

The prairie dog mpox model is very similar to the mpox infection course in humans and is characterized by a 10- to 13-day incubation period, followed by about 2 days of fever, ultimately leading to the appearance of generalized lesions [57]. In prairie dogs, BCV was shown to improve survival when given shortly after mpox exposure [57]. Taken together, these models indicate that early treatment with BCV is key for treatment efficacy, and ideally this would be taken as soon as infection is known, or as soon as prodrome or lesions develop.

Toxicity

Pooled data from phase I/II/III studies indicate that common adverse effects with BCV include gastrointestinal and hepatocellular toxicity (Table 1) [58]. These adverse effects appear to be dose and frequency related [58]. Compared with CDV, BCV has lower rates of nephrotoxicity and the advantage of oral administration [58].

Clinical Data in Humans

Brincidofovir has been administered to select patients with infections caused by poxviruses. A summary of the published case reports is presented in Table 2. Additionally, BCV has been evaluated for the prevention and treatment of other dsDNA viruses. A phase II trial studying BCV for primary CMV prophylaxis in allogeneic hematopoietic cell transplant (HCT) recipients showed a significant reduction in CMV events in the 100-mg twice-weekly arm compared with placebo. In this trial, diarrhea was dose-limiting at 200 mg twice weekly [59]. Nevertheless, a subsequent phase III trial evaluating the same indication failed to demonstrate a difference in clinically significant CMV infection between BCV 100 mg twice weekly and placebo and showed a higher rate of serious adverse events in the BCV arm. The increased rate of adverse events was mostly driven by acute graft-versus-host disease and diarrhea. Additionally, there was slightly higher all-cause mortality at week 24 in the BCV group [60]. Another phase II trial evaluated BCV for preemptive therapy of adenovirus viremia in allogeneic HCT recipients and showed a numerically lower rate of treatment failure and all-cause mortality in the BCV 100-mg twice-weekly arm. This did not reach statistical significance, likely due to a lack of power. Nevertheless, the BCV group had a higher rate of acute graft-versus-host disease [61]. Additional retrospective studies of BCV have shown its activity when used for resistant CMV and herpes simplex treatment [62] and for herpes simplex and varicella zoster prophylaxis [63]. There is currently an ongoing phase II clinical trial evaluating intravenous BCV in patients with adenovirus infection (NCT04706923).

TECOVIRIMAT

Basic Pharmacology

Tecovirimat (ST-246) was FDA approved in 2018 for the treatment of smallpox and is marketed under the brand name TPOXX. Tecovirimat has activity against orthopoxviruses but has no notable activity against other dsDNA viruses. Tecovirimat targets the V061 gene in cowpox, a gene that is homologous to the vaccinia virus F13L gene. This encodes for membrane protein p37, which is a well-conserved protein in orthopoxviruses and is responsible for the formation of extracellular enveloped virus (EV) [64, 65]. EV is thought to be the major contributor to cell-to-cell transmission and transmission through the bloodstream to distant tissues [65, 66]. Tecovirimat does not inhibit DNA or protein synthesis and does not inhibit the formation of mature virus, which remains in the host cell until cell lysis (Figure 3) [64].

Resistance to tecovirimat can occur with a single amino acid mutation at position 277 [65]. It is unknown if mutation of the p37 protein confers a fitness disadvantage to orthopoxviruses, although vaccinia viruses with engineered mutations in the F13L gene had decreased plaque size and a decrease in extracellular EV formation [65]. Tecovirimat has activity against CDV-resistant vaccinia virus strains, and there is no documented cross-resistance between tecovirimat and CDV or BCV [65].

Pharmacokinetic Data

Tecovirimat is available in IV and oral formulations. When administered in the fed state, tecovirimat can achieve a better absorption, with up to 1.6 times greater Cmax than at fasting. Tecovirimat appears to have saturable absorption at doses greater than 400 mg, with higher doses resulting in nonproportional increases in Cmax and area under the curve (AUC) [68].

Animal Data

Tecovirimat has been shown to be effective in multiple animal models of orthopoxviruses, including against mpox virus in macaque monkeys [69, 70] and prairie dogs [71]. Tecovirimat decreases lesion severity even when administration is delayed [69, 72]. Administration of tecovirimat within 4–72 hours after poxvirus exposure demonstrated efficacy at preventing death and a reduction in the severity of lesions in various animal models [70, 73–75]. Tecovirimat has been shown to decrease viral spread of vaccinia virus to distant tissues [64, 66]. Altogether, tecovirimat is a promising agent in animal models for the treatment of mpox infection.

Tecovirimat appears to have synergistic activity when co-administered with BCV. In cell culture experiments with cowpox and vaccinia virus, the addition of tecovirimat reduced EC₅₀ values of BCV [76]. In mice infected with cowpox, BCV and tecovirimat appeared to be synergistic, especially when therapy was significantly delayed, as the combination reduced mortality compared with either drug alone [76].

The duration of treatment with tecovirimat has been studied in various animal models. Fourteen-day courses have been shown to be more protective against death [73]. Courses of less than 5–7 days in duration may lead to rebound of infection, as discontinuation of tecovirimat prior to day 10, when T-cell immunity develops, may lead to worse outcomes [74]. In immunocompromised patients, prolonged courses or combination therapy may need to be considered.

Toxicity

Phase I and II studies of tecovirimat have demonstrated that tecovirimat is safe and well tolerated (Table 1) [69]. Due to poor water solubility, IV tecovirimat is solubilized with B-cyclodextrin. Although the drug labeling recommends caution in patients with renal impairment, previous studies evaluating IV voriconazole and remdesivir, which are formulated with B-cyclodextrin, have not shown significant toxicities of this solubilizer in patients with renal impairment [77, 78]. Furthermore, rapid infusion with the IV product should be avoided, as elevated Cmax following rapid infusion in animal models resulted in reversible central nervous system toxicities, including ataxia, tremors, and lethargy [79].

Clinical Data in Humans

Tecovirimat has been administered to select human patients with infections caused by orthopoxviruses. A summary of the case reports is presented in Table 3. Two patients received it for mpox. Limited details are available about the first patient, except for complete recovery [80]. The second patient received a 2-week oral course initiated 5 days after rash onset, achieved full recovery with no treatment-related complications, and was discharged from the hospital after a 10-day stay [20]. Of interest, 1 immunocompromised patient developed resistance to tecovirimat during a prolonged treatment course for progressive vaccinia; however, he received BCV concomitantly and he completely recovered [67]. There are 4 registered ongoing clinical trials evaluating tecovirimat as oral or intravenous formulation for orthopoxviral exposure (NCT02080767, NCT05380752) and its safety, tolerability, and pharmacokinetics when administered for 28 days (NCT04971109, NCT04957485).

FUTURE DIRECTIONS

In conclusion, the 3 antivirals reviewed here demonstrate activity against mpox. Given their favorable tolerability profile, tecovirimat and BCV are promising therapeutic options. Larger studies should seek to identify the patients at highest risk of complications due to mpox infection (eg, immunocompromised, pregnant women, children, older adults) who might benefit the most from antiviral therapy, and to determine the optimal starting time and duration of antiviral therapy.

References

Author notes