Notes from the Field: Mpox Cluster Caused by Tecovirimat-Resistant Monkeypox Virus - Five States, October 2023-February 2024.

The antiviral drug tecovirimat* has been used extensively to treat U.S. mpox cases since the start of a global outbreak in 2022. Mutations in the mpox viral protein target (F13 or VP37) that occur during treatment can result in resistance to tecovirimat† (1,2). CDC and public health partners have conducted genetic surveillance of monkeypox virus (MPXV) for F13 mutations through sequencing and monitoring of public databases. MPXV F13 mutations associated with resistance have been reported since 2022, typically among severely immunocompromised mpox patients who required prolonged courses of tecovirimat (3-5). A majority of patients with infections caused by MPXV with resistant mutations had a history of tecovirimat treatment; however, spread of tecovirimat-resistant MPXV was reported in California during late 2022 to early 2023 among persons with no previous tecovirimat treatment (3). This report describes a second, unrelated cluster of tecovirimat-resistant MPXV among 18 persons with no previous history of tecovirimat treatment in multiple states.

Tecovirimat Use under Expanded Access to Treat Mpox in the United States, 2022-2023.

BACKGROUND: During the ongoing outbreak of clade II monkeypox virus (MPXV), many U.S. patients were prescribed tecovirimat, an antiviral drug that was made available under an expanded access Investigational New Drug (EA-IND) program. We evaluated EA-IND data to summarize characteristics of treated patients, outcomes, and serious adverse events (SAEs). METHODS: We evaluated data from patients prescribed tecovirimat from May 29, 2022, through July 10, 2023. Baseline patient characteristics, clinical courses, and outcomes were evaluated via intake forms, outcome forms, and patient diaries. Data were summarized in aggregate by human immunodeficiency virus (HIV) status and by comorbidities of special interest. Reported SAEs were also compiled. RESULTS: Tecovirimat was prescribed for over 7100 patients in the United States, most often for lesions in sensitive anatomical areas, such as certain anogenital lesions (83.5%; 5135 out of 6148 patients), and pain (52.5%; 3227 out of 6148 patients). The demographic and clinical characteristics mirrored those of patients worldwide. Among the 7181 patients with returned intake forms, 1626 also had returned outcome forms (22.6%). Many patients with severe immunocompromise (e.g., HIV with CD4 counts <200 cells/µl) received multiple courses of tecovirimat (43.1%; 22 out of 51 patients), including intravenously, and often experienced poor outcomes (35.3%; 18 out of 51 patients). Overall, 223 SAEs and 40 deaths were reported. Most SAEs were among patients who were severely immunocompromised, one of whom experienced hallucinations after tecovirimat was administered at twice the standard dose. CONCLUSIONS: Tecovirimat was used extensively. The returned EA-IND data suggest that life-threatening or protracted infections occurred in persons who were severely immunocompromised. SAEs were not commonly reported. The EA-IND data are not definitive; controlled clinical trial data are essential to elucidating if and how tecovirimat should be used.

Antivirals for monkeypox virus: Proposing an effective machine/deep learning framework.

Monkeypox (MPXV) is one of the infectious viruses which caused morbidity and mortality problems in these years. Despite its danger to public health, there is no approved drug to stand and handle MPXV. On the other hand, drug repurposing is a promising screening method for the low-cost introduction of approved drugs for emerging diseases and viruses which utilizes computational methods. Therefore, drug repurposing is a promising approach to suggesting approved drugs for the MPXV. This paper proposes a computational framework for MPXV antiviral prediction. To do this, we have generated a new virus-antiviral dataset. Moreover, we applied several machine learning and one deep learning method for virus-antiviral prediction. The suggested drugs by the learning methods have been investigated using docking studies. The target protein structure is modeled using homology modeling and, then, refined and validated. To the best of our knowledge, this work is the first work to study deep learning methods for the prediction of MPXV antivirals. The screening results confirm that Tilorone, Valacyclovir, Ribavirin, Favipiravir, and Baloxavir marboxil are effective drugs for MPXV treatment.

Expanded Access Programme for the use of tecovirimat for the treatment of monkeypox infection: A study protocol for an Expanded Access Programme.

BACKGROUND: Monkeypox is a viral zoonotic disease commonly reported in humans in parts of Central and West Africa. This protocol is for an Expanded Access Programme (EAP) to be implemented in the Central African Republic, where Clade I monkeypox virus diseases is primarily responsible for most monkeypox infections. The objective of the programme is to provide patients with confirmed monkeypox with access to tecovirimat, a novel antiviral targeting orthopoxviruses, and collect data on clinical and virological outcomes of patients to inform future research. METHODS: The study will be conducted at participating hospitals in the Central African Republic. All patients who provide informed consent to enrol in the programme will receive tecovirimat. Patients will remain in hospital for the duration of treatment. Data on clinical signs and symptoms will be collected every day while the patient is hospitalised. Blood, throat and lesion samples will be collected at baseline and then on days 4, 8, 14 and 28. Patient outcomes will be assessed on Day 14 -end of treatment-and at Day 28. Adverse event and serious adverse event data will be collected from the point of consent until Day 28. DISCUSSION: This EAP is the first protocolised treatment programme in Clade I MPXV. The data generated under this protocol aims to describe the use of tecovirimat for Clade I disease in a monkeypox endemic region of Central Africa. It is hoped that this data can inform the definition of outcome measures used in future research and contribute to the academic literature around the use of tecovirimat for the treatment of monkeypox. The EAP also aims to bolster research capacity in the region in order for robust randomised controlled trials to take place for monkeypox and other diseases. TRIAL REGISTRATION: {2a & 2b}: ISRCTN43307947.

The global patent landscape of emerging infectious disease monkeypox.

BACKGROUND: Monkeypox is an emerging infectious disease with confirmed cases and deaths in several parts of the world. In light of this crisis, this study aims to analyze the global knowledge pattern of monkeypox-related patents and explore current trends and future technical directions in the medical development of monkeypox to inform research and policy. METHODS: A comprehensive study of 1,791 monkeypox-related patents worldwide was conducted using the Derwent patent database by descriptive statistics, social network method and linear regression analysis. RESULTS: Since the 21st century, the number of monkeypox-related patents has increased rapidly, accompanied by increases in collaboration between commercial and academic patentees. Enterprises contributed the most in patent quantity, whereas the initial milestone patent was filed by academia. The core developments of technology related to the monkeypox include biological and chemical medicine. The innovations of vaccines and virus testing lack sufficient patent support in portfolios. CONCLUSIONS: Monkeypox-related therapeutic innovation is geographically limited with strong international intellectual property right barriers though it has increased rapidly in recent years. The transparent licensing of patent knowledge is driven by the merger and acquisition model, and the venture capital, intellectual property and contract research organization model. Currently, the patent thicket phenomenon in the monkeypox field may slow the progress of efforts to combat monkeypox. Enterprises should pay more attention to the sharing of technical knowledge, make full use of drug repurposing strategies, and promote innovation of monkeypox-related technology in hotspots of antivirals (such as tecovirimat, cidofovir, brincidofovir), vaccines (JYNNEOS, ACAM2000), herbal medicine and gene therapy.

Viruela símica: reporte de un caso clínico / Monkey pox: clinical case report

La viruela símica (monkey pox) es una enfermedad infecciosa causada por un virus del género Orthopoxvirus, usualmente acompañada de síntomas sistémicos como: fiebre, cefalea, mialgias, astenia, erupciones cutáneas o lesiones mucosas. Esta enfermedad se transmite por contacto físico con personas infectadas, materiales o animales infectados. Presentamos el caso de un paciente de 6 años que acude a consulta de Atención Primaria por presentar sintomatología compatible con esta sospecha clínica. Se diagnostica viruela símica bajo reacción en cadena de la polimerasa (PCR) positiva y se da de alta con manejo sintomático ambulatorio. (AU)

Monkeypox is a zoonosis-type disease caused by a virus of the genus Orthopoxvirus. Usually accompanied by systemic symptoms such as fever, headache, myalgia, asthenia, skin rashes or mucosal lesions. This disease is transmitted by physical contact with infected people, infected materials or animals. We present the case of a 6-year-old patient who came to primary care for symptoms compatible with clinical suspicion. Monkeypox was diagnosed under positive PCR and discharged with outpatient symptomatic management. (AU)

Human monkeypox virus: Epidemiologic review and research progress in diagnosis and treatment.

Monkeypox virus (MPXV) is responsible for causing a zoonotic disease called monkeypox (mpox), which sporadically infects humans in West and Central Africa. It first infected humans in 1970 and, along with the variola virus, belongs to the genus Orthopoxvirus in the poxvirus family. Since the World Health Organization declared the MPXV outbreak a "Public Health Emergency of International Concern" on July 23, 2022, the number of infected patients has increased dramatically. To control this epidemic and address this previously neglected disease, MPXV needs to be better understood and reevaluated. In this review, we cover recent research on MPXV, including its genomic and pathogenic characteristics, transmission, mutations and mechanisms, clinical characteristics, epidemiology, laboratory diagnosis, and treatment measures, as well as prevention of MPXV infection in light of the 2022 and 2023 global outbreaks. The 2022 MPXV outbreak has been primarily associated with close intimate contact, including sexual activity, with most cases diagnosed among men who have sex with men. The incubation period of MPXV infection usually lasts from 6 to 13 days, and symptoms include fever, muscle pains, headache, swollen lymph nodes, and a characteristic painful rash, including several stages, such as macules, papules, blisters, pustules, scabs, and scab shedding involving the genitals and anus. Polymerase chain reaction (PCR) is usually used to detect MPXV in skin lesion material. Treatment includes supportive care, antivirals, and intravenous vaccinia immune globulin. Smallpox vaccines have been designed with four givens emergency approval for use against MPXV infection.

Caso probable de síndrome de reconstitución inmune por mpox en una persona con inmunosupresión avanzada por VIH / Probable case of mpox immune reconstitution inflammatory syndrome (IRIS) in a person with HIV disease

Se presenta el caso clínico de persona viviendo con VIH, con mala adherencia a tratamiento, sin vacunación previa para mpox, que evolucionó con un cuadro clínico probable de síndrome de reconstitución inmune posterior a reinicio de TAR, debido a la progresión de las lesiones cutáneas. Recibió tratamiento con tecovirimat por siete días, con evolución clínica favorable. Corresponde al primer caso reportado que recibió terapia con tecovirimat en Chile.

We report a clinical case of a person living with HIV with poor adherence to treatment, no previous mpox vaccination, who had a probable mpox syndrome immune reconstitution after restarting ART, due to worsening of skin lesions. He received treatment with tecovirimat for 7 days, clinically improved and was discharged in good condition. We reported this first clinical case that received tecovirimat in Chile.

Update on monkeypox virus infection: Focusing current treatment and prevention approaches.

BACKGROUND: While the world is still facing the global pandemic COVID-19, another zoonosis monkeypox (Mpox) has emerged posing a great threat to society. Insight into the pathogenesis, symptoms, and management strategies will aid in the development of potent therapeutics for the treatment of monkeypox virus infection. OBJECTIVES: To get insight into the current treatment and prevention strategies will aid in effectively coping with the disease. METHODS: For obtaining information regarding the ongoing treatment and prevention strategies and the drugs under pipeline, we referred to Google Scholar, Pub Med, Pub Chem, and WHO official site. RESULTS: There are a few drugs that came out to be effective for the treatment of Mpox. Tecovirimat acts by inhibiting viral replication and viral wrapping. Another drug is cidofovir, which hinders the activity of viral DNA polymerase but has the drawback of nephrotoxicity. To overcome this, a conjugate of cidofovir is being used-known as brincidofovir-which has a similar mechanism as cidofovir but lesser toxicity. Ribavirin acts via inhibiting inosine monophosphate dehydrogenase (IMPDPH) thus disrupting viral translation. It also interferes with helicase activity. Tiazofurin, Adenosine N1 oxide, and HPMPA have shown efficacy in in-vitro studies by inhibiting IMPDH, DNA polymerase, and viral mRNA translation respectively. In-silico studies have proven the effect of nilotinib, simeprevir, and dihydroergotamine for Mpox treatment. They have shown binding affinity for proteins required for the growth and release of MPXV. Vaccines have also been employed for the prevention of Mpox, which includes JYNNEOS, ACAM2000, and VIGIV. CONCLUSION: This review highlights the pathogenesis of the virus, disease manifestations, drugs, and vaccines that are being used and those under pipeline for the treatment and prevention of Mpox.

Computational drug repurposing for viral infectious diseases: a case study on monkeypox.

The traditional method of drug reuse or repurposing has significantly contributed to the identification of new antiviral compounds and therapeutic targets, enabling rapid response to developing infectious illnesses. This article presents an overview of how modern computational methods are used in drug repurposing for the treatment of viral infectious diseases. These methods utilize data sets that include reviewed information on the host's response to pathogens and drugs, as well as various connections such as gene expression patterns and protein-protein interaction networks. We assess the potential benefits and limitations of these methods by examining monkeypox as a specific example, but the knowledge acquired can be applied to other comparable disease scenarios.

Burdening Perspectives and Treatment Modalities of Monkeypox: A Central Dogma.

The monkeypox virus (MPXV), belonging to the genus Orthopoxvirus, is responsible for causing the zoonotic illness known as Monkeypox. The virus was initially identified during an outbreak at a Danish Zoo in 1958 and has since been found to infect various mammal species worldwide. While African squirrels and other rodents are believed to be the primary hosts, determining the natural host has proven challenging. While MPXV can be studied using different animal models in laboratory settings, understanding its natural transmission routes remains complex and species-dependent. Recent developments have elevated the global health concern surrounding Monkeypox, leading to its designation as a Global Health Emergency of International Concern on 23 July 2022. Enhancing surveillance and case detection is crucial in navigating the unpredictable epidemiology of this re-emerging disease. Human infections with the monkeypox virus are becoming less frequent due to population growth and economic improvements. Monkeypox, similar to smallpox, can potentially be controlled and eradicated in the future through vaccines, appropriate treatment, and personal protective equipment.

Mini Review on Clinical Aspects of Monkeypox.

Monkeypox is a disease caused by the monkeypox virus, which is a type of orthopox virus that comes from the virus family Poxviridae. Its first case reported in animals and humans was in 1958 and 1970, respectively. It is a viral zoonosis disease with two modes of transmission: animal to human (via direct contact or eating the meat of an infected animal) and human to human (via contact or contact with skin lesions, body fluids, and infected person's contaminated objects). The literature depicts that monkeypox is less contagious among individuals in contrast to smallpox; the infection chain of monkeypox is nearly five to six patients approximately. It has two clades, the West African and the Central African (the Congo basin). The Congo basin subgroup of monkeypox is highly transmissible and severe. The symptoms of monkeypox include fever, lethargy, headache, lymphadenopathy, myalgia, myodynia, fainting, shivers, backache, and rashes on the face and extremities. The most common symptom of monkeypox is lymphatic hyperplasia or, lymph adenopathy or swollen lymph nodes. It is proven to be very useful in the diagnosis of monkeypox. The antiviral drugs that are used for its treatment are tecovirimat, brincidofovir and cidofovir. Tecovirimat has fewer side effects and it shows better therapeutic action in comparison to brincidofovir and cidofovir. For the prevention of monkeypox, the Center for Disease Control and Prevention recommends the administration of the same vaccine used for smallpox named INVAMUNE, which is currently in its third generation. Its first and second generations have adverse side effects in patients having HIV or atopic dermatitis.

Mpox vaccination and treatment: a systematic review.

The Human monkeypox virus (mpox) belongs to the Poxviridae family, characterized by double-stranded DNA. A 2022 outbreak, notably prevalent among men who have sex with men, was confirmed by the World Health Organization. To understand shifting prevalence patterns and clinical manifestations, we conducted a systematic review of recent animal and human studies. We comprehensively searched PubMed, Scopus, Web of Science, Cochrane Library, and Clinicaltrials.gov, reviewing 69 relevant articles from 4,342 screened records. Our analysis highlights Modified Vaccinia Ankara - Bavarian Nordic (MVA-BN)'s potential, though efficacy concerns exist. Tecovirimat emerged as a prominent antiviral in the recent outbreak. However, limited evidence underscores the imperative for further clinical trials in understanding and managing monkeypox.

A Case of Neonatal Monkeypox Treated With Oral Tecovirimat.

Since the Monkeypox virus outbreak erupted in May 2022, infection has been reported across all ages. Few cases exist in the medical literature about Monkeypox infection in neonates, and little is known about its clinical manifestations, disease course, or side effects of available antiviral agents in this age group. In this report, we describe the case of a 10-day-old neonate from the southern United States who presented with fevers and generalized papulopustular rash. She was treated empirically as a febrile neonate but mpox infection was suspected early because of the characteristic exanthem and its similarity to her mother's rash that she had developed a few days before the patient's presentation. Oral tecovirimat was initiated on the third day of admission and mpox was later confirmed by polymerase chain reaction analysis. The patient tolerated oral tecovirimat well and experienced a favorable outcome without lasting effects of infection.

Clinical considerations on monkeypox antiviral medications: An overview.

Monkeypox (mpox), a virus belonging to the orthopoxvirus family, can cause a zoonotic infectious disease with morbidity and cosmetic complications. Therefore, effective antiviral drugs with appropriate safety profiles are important for the treatment of patients with mpox. To date, there is no FDA-approved drug for the treatment of mpox. However, tecovirimat, brincidofovir, and cidofovir are the candidate therapies for the management of mpox. Given the safety concerns following the use of these medications, we aimed to review evidence on the clinical considerations of mpox antiviral medications that will be useful to guide clinicians in the treatment approach. Based on the current evidence, tecovirimat has favorable clinical efficacy, safety, and side effect profile and it can be considered as first-line treatment for mpox.

Tratamiento y prevención de la viruela del mono / Treatment and prevention of monkeypox

La viruela del mono es una zoonosis que se contagia principalmente a través del contacto directo con los fluidos y las lesiones cutáneas de personas contagiadas con vesículas aun activas. Aunque el virus fue aislado por primera vez en 1958, y el primer caso humano se identificó en un niño en 1970, en la República Democrática del Congo, la enfermedad ha aumentado progresivamente su incidencia en África, alcanzando en mayo de 2022 transmisión sostenida fuera de este continente. Al ser un virus de nueva introducción en nuestro entorno sanitario, es necesario aprender el patrón epidemiológico en un medio diferente al de las zonas tradicionalmente endémicas y conocer los tratamientos antivirales a nuestro alcance, así como las medidas profilácticas que podrían plantearse, sabiendo que como virus emergente en nuestras regiones las evidencias científicas aun son limitadas. Existen antivirales que han demostrado en modelos animales combatir eficazmente la enfermedad con muy buena tolerancia clínica. Esta enfermedad también ha obligado a revisar las características de las vacunas frente a la viruela, ya que han demostrado un efecto protector frente a la viruela del mono. Por ello, es importante disponer de un documento que recopile toda la información científica publicada a este respecto.(AU)

Monkeypox is a zoonosis that is spread mainly through direct contact with fluids and skin lesions of infected people with vesicles still active. Although the virus was isolated for the first time in 1958 and the first human case was identified in a child in 1970, in the Democratic Republic of the Congo, the disease has progressively increased its incidence in Africa reaching in May 2022 sustained transmission outside this continent. As it is a newly introduced virus in our health system, it is necessary to learn the epidemiological pattern in a different environment from that of traditionally endemic areas and to know the available antiviral treatments, as well as the prophylactic measures that could be considered, knowing that as a virus emerging in our regions, scientific evidence is still limited. There are antivirals that have been shown, in animal models, to effectively combat the disease with very good clinical tolerance. This disease has also forced us to review the characteristics of smallpox vaccines, because they have shown a protective effect against monkeypox. For this reason, it is important to have a document that compiles all the scientific information published in this regard.(AU)

Mpox (formerly monkeypox): pathogenesis, prevention, and treatment.

In 2022, a global outbreak of Mpox (formerly monkeypox) occurred in various countries across Europe and America and rapidly spread to more than 100 countries and regions. The World Health Organization declared the outbreak to be a public health emergency of international concern due to the rapid spread of the Mpox virus. Consequently, nations intensified their efforts to explore treatment strategies aimed at combating the infection and its dissemination. Nevertheless, the available therapeutic options for Mpox virus infection remain limited. So far, only a few numbers of antiviral compounds have been approved by regulatory authorities. Given the high mutability of the Mpox virus, certain mutant strains have shown resistance to existing pharmaceutical interventions. This highlights the urgent need to develop novel antiviral drugs that can combat both drug resistance and the potential threat of bioterrorism. Currently, there is a lack of comprehensive literature on the pathophysiology and treatment of Mpox. To address this issue, we conducted a review covering the physiological and pathological processes of Mpox infection, summarizing the latest progress of anti-Mpox drugs. Our analysis encompasses approved drugs currently employed in clinical settings, as well as newly identified small-molecule compounds and antibody drugs displaying potential antiviral efficacy against Mpox. Furthermore, we have gained valuable insights from the process of Mpox drug development, including strategies for repurposing drugs, the discovery of drug targets driven by artificial intelligence, and preclinical drug development. The purpose of this review is to provide readers with a comprehensive overview of the current knowledge on Mpox.