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Review

A Review on Inosine Pranobex Immunotherapy for Cervical HPV-Positive Patients

Stefan Miladinov Kovachev1 Department of Gynecology, Military Medical Academy, Sofia, BulgariaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0001-6662-3700
ORCID Icon
Pages 2039-2049 | Published online: 02 Jun 2021

Abstract

The purpose of this review was to examine and summarize data for inosine pranobex (IP) immunotherapy in cervical HPV-positive patients. Persistent or recurring cervical human papillomavirus (HPV) infection is a major cause of cervical cancer. Self-clearance and blocking of cervical HPV infection depend on the status of the host immune system. Immunotherapy helps accelerate elimination of the infection. Host immunity is involved in the development of HPV infection. Several mechanisms of interaction between the virus and the immune system have been revealed; however, the mechanisms have not been completely elucidated. A properly functioning immune system impedes HPV progress and helps clear the pathogen from the body. IP has antiviral efficacy because it modulates both cellular and humoral immunities. IP has been on the market since 1971. Nevertheless, it has seldom been administered to treat cervical HPV infections. In this review, Google Scholar, PubMed/MEDLINE, Scopus, Cochrane Library, and Research Gate were searched for the period 1971–2021. Prospective controlled trials, observational and retrospective studies, and meta-analysis and reviews on immunotherapy against HPV cervical infection were explored. Prior studies showed strong clinical efficacy of combined and standalone IP therapy in reversing HPV-induced changes in the cervix, preventing disease progression, and clearing the pathogen. IP treatment enhanced host antiviral activity against HPV, delayed or stopped cervical oncogenesis, and rapidly removed HPV from the body.

Introduction

To date, >200 human papillomavirus (HPV) types have been detected.Citation1Citation3 The most common HPV transmission route is sexual contact.Citation2 Sexually active individuals will acquire ≥ 1 anogenital HPV genotype at some point in their lives.Citation4 Sensitive PCR monitoring has indicated that most HPV infections are cleared by the immune system and disappear within 1–2 y without clinical complications.Citation5,Citation6 Epidemiological evidence for HPV carcinogenicity was first presented by zurHausen in 1983 and accepted in 1995 by the International Agency for Cancer Research (IARC) of the World Health Organization (WHO).Citation4 HPV carcinogenicity was first established for cervical precancers and cancers. Cervical carcinogenesis is a multi-step process starting with HPV infection of the cervical epithelium. However, cancer onset occurs after persistent or recurring HPV infection.Citation7 There is ample evidence to support the hypothesis that host immunological status and HPV-induced immune changes are responsible for persistent HPV infection and subsequent development of cervical neoplasia.Citation7Citation9 The immune system eliminates the virus and recognizes the tumor antigen associated with cervical carcinogenesis.Citation7,Citation9 Both cellular and humoral immunity are vital for clearing cervical HPV infection.Citation8,Citation9

To date, no antiviral drugs effectively kill or hinder the progress of cervical HPV.Citation10 Hence, host immunity alone must fend off and clear genital HPV.Citation11 However, the host immune response may be inadequate and require modulation.Citation12 Suppressive modulations may be required when the host immune response is too strong. In contrast, immunostimulation is needed when host immunity is weak.Citation12

Immunotherapy is an essential treatment modality for microbial infections, malignancies, and other forms of pathogenesis.Citation13 Immunotherapeutic agents may be specific and nonspecific.Citation14 Immunomodulators are nonspecific immunotherapeutic agents and can be immunostimulants or immunosuppressants.Citation15 The former induce nonspecific humoral and cellular immune responses.

Inosine pranobex (IP), also known as inosine acedobendimepranol (INN) or methisoprinol, is an antiviral drug consisting of a 1:3 ratio of inosine and dimepranolacedoben. The latter is a salt of acetamidobenzoic acid and dimethylaminoisopropanol.Citation16 Since 1971, IP has been licensed for the treatment of cell-mediated immunodeficiency associated with human papillomavirus (HPV), herpes simplex virus (HSV), varicella-zoster virus (VZV), cytomegalovirus (CMV), and Epstein-Barr virus (EBV).Citation16

The purpose of this review was to examine and summarize data on IP immunotherapy for cervical HPV-positive patients.

Materials and Methods

Google Scholar, PubMed/MEDLINE, Scopus, Cochrane Library, Research Gate, were searched from 1971 when IP was first licensed until 2021. The main terms used during database search were cervical human papillomavirus infection, clearance, persistence, oncogenesis, immunity, inosine pranobex, and immunomodulation.

Prospective controlled trials, observational and retrospective studies, meta-analysis, and reviews on immunotherapy against HPV cervical infection were examined. The primary outcomes were persistence and clearance of cervical HPV genotypes in women undergoing IP therapy and the onset of low- or high-grade cervical intraepithelial neoplasia (CIN) or LSIL/HSIL (low/high squamous intraepithelial lesions) in patients being monitored for a certain period of time. The overall quality of evidence for immunotherapy against cervical HPV infection was evaluated. Of 108 identified abstracts, 62 full-text articles were reviewed, and 41 studies were included in the synthesis.

Cervical HPV Infection: Self-Clearance and Persistence

Persistence of HPV infection is critical in the development of cervical precancerous lesions and cancer. The main unresolved issues regarding the natural history of HPV are the extent to which the viral infection is self-cleared and the time required for this process.Citation17 Unlike self-clearance, persistence, or the time during which HPV infection remains detectable, is unclear.Citation17,Citation18 Persistence is longer for high-risk than low-risk HPV types.Citation5,Citation19,Citation20 Only ~10% of all HPV infections persisting for several years were strongly associated with a high absolute risk of a precancer diagnosis.Citation21Citation23

Rositch et alCitation24 carried out a meta-analysis of published studies on the persistence and self-clearing of HPV infection and the risks of developing CIN and cervical cancer associated with it.Citation24 They summarized the data for 86 studies involving > 100,000 patients.Citation24 The authors concluded that ~50% of the HPV infections persisted within the last 6–12 mo.Citation24 Cervical HPV tests at 12-mo intervals can identify women at an increased risk of high-grade CIN as a result of persistent HPV infection.Citation24 The PATRICIA study comprised 4825 women with cervical HPV infections.Citation25 The aim of that trial was to determine the proportions of HPV infections that are cleared or progress to CIN.Citation25 Persistent infection with high-risk HPV genotypes more frequently leads to CIN compared to persistent infections with low-risk HPV genotypes.Citation25 High-risk HPV type infections were the least likely to be cleared.Citation25 Miranda et alCitation26 surveyed 569 women in Brazil for persistence and clearance of HPV infection over 24 mo. Eighty-nine of these patients were HPV positive.Citation26 After 24 mo, HPV persistence and clearance were observed in 59.6% and 40.4% of the women, respectively.Citation26 High-risk HPV genotypes persist over a longer period of time and play a major role in CIN and cervical cancer pathogenesis.Citation26

Cervical HPV clearance and persistence depend on host immunity.Citation7,Citation27Citation30 Adequate immune response is vital to the self-clearance of numerous cervical HPV types.Citation27,Citation28,Citation30 Ineffective immune response is associated with insufficient activation of congenital immunity, non-inclusion of the adaptive immune response, or strong viral persistence.Citation7,Citation29,Citation31,Citation32 Nguyen et al followed systemic and mucosal immune responses to cervical HPV in women who underwent radical hysterectomy for cervical cancer (HCC) or loop conization for cervical dysplasia.Citation8 They analyzed HPV-specific antibodies through ELISA and cytokine assays performed with the Linco cytokine multiplex method using Luminex technology on vaginal washes.Citation8 They found relatively lower levels of HPV16 E7-specific immunoglobulin A (IgA) in the vaginal wash of women with cervical cancer and cervical dysplasia compared with the control. Neither Th1-nor Th2-type cytokine induction was detected in the cervical cancer group.Citation8 Thus, selective downregulation of local HPV-specific IgA responses occurred in the cervical cancer patients.Citation8

In HPV-induced carcinogenesis, interactions between virally infected keratinocytes and the cervical local immune response can determine the course of the disease.Citation30 Elucidating these interactions could help develop innovative diagnostic immune tests to determine cervical pre-cancer progression and design novel immunotherapy approaches targeting the mechanisms and pathways involved in HPV-induced carcinogenicity.Citation30

Cervical HPV Infection and Host Immune Response

HPV is an epitheliotropic virus that exclusively attacks epithelial cells and primarily spreads and acts locally in this type of tissue. In the cervix, HPV infects the keratinocytes in the basal layer of the cervical epithelium in the transformation zone of the cervix.Citation27,Citation30,Citation33,Citation34 Viral replications markedly increase in differentiated epithelial layers that have undergone recent desquamation.Citation27,Citation35 Viral particles are assembled when differentiated keratinocytes die and the virus is released during desquamation into the ambient environment.Citation35 Downregulated protein expression in the lower epithelial layers, high non-cytolytic genomic replication, and the absence of a viremic phase enable the virus to evade immune system recognition.Citation33,Citation34

Keratinocytes infected by HPV initiate an adaptive immune responseCitation36 as they are part of innate immunity. Antigens may not be fully represented in keratinocytes but the cells nonetheless upregulate the cytokines TH1 and TH2 and cytotoxic responses in CD4+ and CD8+ memory T cells, respectively.Citation7,Citation30,Citation36 CD4+ T helper (Th1 and Th2) and CD8+ T cell responses were identified in patients with genital HPV-induced warts.Citation37 Comparisons of HPV6 and HPV11 antigen-specific T cell responses between venereal wart patients and healthy controls disclosed low frequencies of IFN-γ-producing CD4+ and CD8+ T cells in HPV-infected women.Citation37 The relative number of IL-4-expressing CD4+ T cells was significantly higher in infected women than in normal women.Citation37 The observed change from Th1 to Th2 in HPV-infected patients was a consequence of a weakened immune response caused by the HPV infection. A direct effect of depressed CD8 T cell activity is delayed or poor genital wart clearing.Citation37 In the female genital tract, keratinocytes express several Toll-like receptors (TLR) on the cell surfaces (TLR-1, TLR-2, TLR-4, TLR-5, and TLR-6) and in the endosomes (TLR-3 and TLR-9).Citation7,Citation30,Citation38 TLR are a family of immunological receptors that recognize pathogen-related molecular patterns (PAMPs) and induce congenital and adaptive immune responses.Citation7,Citation28 TLRs recognize viral nucleic acids. TLR-3 recognizes one-sided-chain RNA (dsRNA) while TLR-7 and TLR-8 recognize single-chain RNA (ssRNA) and TLR-9 recognizes CGG-rich DNA.Citation28 Activated TLRs receptors induce cytokine production and strong anti-inflammatory responses.Citation39 Switching on TLR-9 in keratinocytes initiates the production of TNF-α, IL-8, CCL2, CCL20, CXCL9, and type 1 IFN.Citation40,Citation41 The second level is adaptive immunity via cytotoxic T lymphocytes (CTLs) targeting HPVE2 and HPVE6 and eliminating HPV-infected cells.Citation41 CD4+ and CD8+T lymphocytes predominate in cervical epithelium.Citation33 Langerhans cells are located on the surface epithelial layers.Citation33 When HPV attacks the epithelium, Langerhans cells switch on and activate T lymphocytes.Citation42 Adequate T cell immune responses regress HPV-induced lesions and clear local HPV infection.Citation43 Inactive T cell immune responses are associated with long-term viral persistence and cervical cancer induction.Citation33

HPV can evade encounters with the immune system.Citation28,Citation33,Citation41 As HPV lacks a viremic phase, immune cells cannot easily enter into contact with it.Citation28,Citation33 HPV attacks basal epithelial layers of the cervix as immunocompetent Langerhans cells occur only in the surface epithelial layers and avoid invoking the T cell immune response.Citation33,Citation44 HPV does not cytolyse the cervical epithelium. In this way, it attenuates inflammatory and immune signal responses and can persist incognito.Citation41,Citation44 HPV also avoids the immune response by downregulating its oncogenes throughout the initial life cycle and only synthesizing immunogens such as L1 and L2 capsid proteins in surface epithelial layers that undergo desquamation.Citation33,Citation34,Citation41

Evasion of a local immune response is required for the development of successful cervical HPV infection.Citation33,Citation44 Therefore, the application of therapeutic agents stimulating innate immunity may effectively prevent the onset of local HPV infections.

Inosine Pranobex: Immunomodulatory Mechanism

Inosine acedobendimepranol (IAD) is a synthetic purine derivative consisting of a 3:1 ratio of p-acetamidobenzoic acid salt of N,N-dimethyl-amino-2-propanol (DiP.PAcBA) and the β polymorph of the β anomer of inosine.IAD has immunomodulatory and antiviral propertiesCitation15 and is registered in numerous countries under the brand names Immunovir, Isoprinosine, Viruxan, Inosiplex, Methisoprinol, and Inosine Pranobex.Citation15

IP was introduced in 1971 and several studies from the 1970s and 1980s showed that it did not induce serious side effects and was well tolerated by patients.Citation45,Citation46 At high doses and after long-term use, the metabolites of IP may cause reversible increases in serum urinary uric acid and nausea.Citation45,Citation46

Several studies have demonstrated that IP is antiviral and immunomodulatory. However, its exact mechanisms are not fully understood.Citation47 IP affects cellular and humoral immunity and is antiviral by immunomodulation.Citation47

IP stimulates a Th1 cell response characterized by proinflammatory cytokine (IL-2 and IFN-c) upregulation in mitogen- and antigen-activated cells.Citation48,Citation49 Induction of IL-2 and IFN-c activates T lymphocyte maturation and differentiation and the lymphoproliferative response.Citation49,Citation50 Similarly, IP modulates T lymphocyte and natural killer cell cytotoxicity and T8 suppressor and T4 helper cell function and increases the numbers of immunoglobulin G (IgG) and complement-surface markers.Citation47 Certain studies investigated the influences of IP on Th1- and Th2-related cytokines. When the lymphocytes were at rest, the cytokine levels remained constant.Citation49,Citation51 Lymphocyte stimulation with IP upregulated IL-2, interferon c (IFN-c),and tumor necrosis factor alpha (TNF-a) and downregulated IL-4, IL-5, and IL-10.Citation49,Citation51

IFN-c expression and IP block IL-10 production. Moreover, IP downregulates other anti-inflammatory cytokines and may block their effects on the immune response.Citation52 IP administration increases the number and activity of natural killer cells (NK).Citation47,Citation53 NK activity in eosinophils rises in response to increases in the numbers of lgG and complement-surface markers as well as macrophage, monocyte, and neutrophil chemotaxis and phagocytosis.Citation51,Citation53

IP suppresses the synthesis and translational ability of lymphocyte mRNA and inhibits viral RNA synthesis by:

  • 1) inosine-mediated inclusion of orotic acid in polyribosomes;

  • 2) suppression of polyadenylic acid capture by viral mRNA; and

  • 3) molecular reorganization and a nearly threefold increase in the density of intramembrane plasma particles (IMP).Citation54

The humoral immune response consists of activating B lymphocyte transformation into plasma cells and initiating antibody production.Citation55 B lymphocyte transformation may be a response to IP action but also a consequence of the effects of IP on macrophages and T helper cells.Citation47 IP stimulates certain immune mediators, promotes Th1 cells, and inhibits Th2 cells.Citation50 Most of the 21 healthy patients undergoing daily administration of 4 g IP in a Bulgarian study presented with rapid immune responses, increases in the numbers of their lymphocytes, and circadian fluctuation of these parameters in their peripheral blood.Citation56 In another Bulgarian study, serum cytokine levels were measured in 10 healthy volunteers during and after IP treatment (1 g IP, 3x daily, 3 wks).Citation48 Increases in proinflammatory cytokine levels were observed.Citation48 Another trial evaluated lymphocyte subsets [CD19+ B cells, CD3+ T cells, CD4+ T helper cells, FoxP3hi/CD25hi/CD127lo regulatory T cells (Tregs), CD3-/CD56+ NK cells, and CD3+/CD56+ NKT cells], serum immunoglobulins, and IgG subclasses in ten healthy volunteers being administered 4 g IP daily for 14 d.Citation15 NK cell counts increased over time and recurred at the end of the study. Furthermore, different high/low Treg and T helper fractions were detected during the study period.Citation15

The effects of IP on the immune systems of patients with different diseases were also investigated. Herpes virus-infected patients had higher lymphocyte transformation rates than healthy controls.Citation57 In patients with autoimmune diseases and chronic active hepatitis B, IP therapy increased the numbers of active T cell rosettes and enhanced responses to mitogen activation.Citation58,Citation59 High NK cell activity and elevated numbers of CD4+ T helper cells were observed in patients with chronic fatigue syndrome undergoing IP therapy.Citation60

Despite the foregoing studies and their findings, the precise immunomodulatory mechanism of IP remains to be clarified.

Cervical HPV Infection and IP Immunotherapy

The first studies on IP administration to patients with genital HPV infection were published in the 1970s and 1980s soon after the drug was launched. Most reports evaluated the clinical efficacy of IP combined with cryotherapy, surgery, or electrosurgery of genital condylomata. In most cases, clinical efficacy of the combination therapies surpassed that of IP administration alone. Sadoul and Beuret followed two groups of patients with cervical or vulvovaginal condylomata.Citation61 They were treated either with CO2 laser or with CO2 laser plus IP.Citation61 Monotherapy was less efficacious than the combination treatments.Citation61 Combination therapy consisting of CO2 laser plus IP significantly reduced the number of recurring condyloma acuminate.Citation61 Mohanty and Scott compared the efficacies of IP, conventional therapy, and their combinations in 165 patients with genital warts.Citation62 Whereas conventional therapy alone had 41% efficacy, the combination of IP plus conventional therapy increased efficacy to 94%.Citation62 The patients undergoing IP therapy in this study presented with relatively higher numbers of B cells.Citation62 In a multicenter, prospective, randomized, placebo-controlled study, Davidson-Parker et al administered 3 g IP daily for 4 wks to 55 patients with genital warts.Citation63 The IP therapy improved the relative clinical efficacy of the conventional treatment (podophyllin or trichloroacetic acid).Citation63 Nejmark et al evaluated the efficacy of combination therapy including IP for the treatment of male genital warts.Citation64 The combination therapy had long-term efficacy and there was only a 7% relapse rate. In contrast, destructive therapy was associated with a 32% relapse rate.Citation64 The authors recommended IP (isoprinosine) for both the complex therapy and prevention of the recurrence of genital warts.Citation64 Tay performed a randomized, placebo-controlled study on the efficacy of IP immunotherapy. They orally administered 1 g IP thrice daily for 6 wks to 55 patients with vulvar HPV infections. There were 22 patients in the IP group and 24 in the placebo group.Citation65 After 2 mo, IP monotherapy proved effective in 14 (63.5%) of the patients. However, only 4 patients (16.7%) in the placebo group presented with substantial improvement in vulvar epithelial morphology (P = 0.005).Citation65 The authors concluded that IP therapy is suitable for the treatment of vulvar HPV infections.Citation65

IP has been on the market since 1971.Nevertheless, our scientific literature and electronic databases searches revealed that only a few studies mainly from the last 20 y have focused on the use of IP in the treatment of patients with cervical HPV infections. It was only in 1983 that zurHausen discovered the connection between cervical HPV infection and carcinogenesis. Moreover, this finding was only accepted as irrefutable scientific fact by the global medical community in the 1990s. It has not been determined why IP immunotherapy has seldom been applied in the treatment of cervical HPV. Furthermore, some of the carcinogenetic mechanisms of HPV have been explored but there are some details that need to be completely clarified. Finally, the relationships among cervical HPV infection, host immune response, and the immune system remain to be established. For these reasons, IP immunotherapy has not been entirely adopted for the treatment of cervical HPV infection.

Most studies on IP administration for cervical HPV infection originated in Eastern Europe, especially Russia.Citation10,Citation66Citation70 It appears that IP administration for immunotherapy against viral diseases is widespread and common in Eastern European countries. provides a summary of the studies on the efficacy of IP in HPV genital infections.

Table 1 Summary of Studies Investigating the Efficacy of IP Therapy in HPV Genital Infections, Especially Cervical Infections

Bitsadze et al reported that combined therapy including IP eliminated HPV in 98% of all cases and lowered the relative relapse rate by threefold.Citation68 Rakhmatulina reviewed numerous Russian studies and concluded that IP against HPV infection had 87.5–97% clinical efficacy in combination therapy and 72.4–95% clinical efficacy in monotherapy.Citation66

Eliseeva et al assessed 5650 women with genital HPV infection from 33 towns in the Russian Federation before and after IP monotherapy and combined treatments.Citation71 After 6 mo, HPV self-clearance without treatment had occurred in 22.6% of all cases.Citation71 The rates of HPV negative cases were 35.5%,54.8%, and 84.2% after conventional, single IP, and combined IP treatments, respectively.Citation71 Therefore, combined IP had the greatest efficacy in terms of clearing genital HPV infection and regressing its associated diseases.Citation71 Pestrikova and Pushkar evaluated the effectiveness of IP treatment in 123 patients with cervical HPV pathology. HPV16 and HPV18 were the most frequently isolated viral types in this study.Citation72 IP treatment stopped CIN1 progression in 96.23±2.62% of all patients.Citation72 Cervical HPV clearance and full recovery were observed in 91.06% of all patients administered IP.Citation72 Pestrikova et al used colposcopy and PAP and cervical PCR tests for HPV16, 18, 31, 33, 35, 39, 45, 51, 52, 56, 58, and 59 to assess the efficacy of IP treatment in 39 women with cervical HPV infection.Citation73 The therapeutic regimen comprised three courses of 3000 mg IP daily at 10-d intervals between courses.Citation73 At the end of the trial, viral load declined to a clinically insignificant level in 17.95% of all women and there was 74.36% cervical HPV clearance.Citation73 Over 3 y, Ordiyants et al followed 80 patients with persistent cervical HPV infection and dysplasia. They had been subjected to a combination of radio-wave conization and three courses of 1000 mg IP thrice daily for 10 d with 14 d intervals between courses.Citation74 At the end of the study, clearance of cervical HPV infection was confirmed for 97.5% of all patients.Citation74 Budanov et al assessed cervical HPV infection in 100 women aged 19–35 y.Citation67 Forty-four of the patients were excluded as they had mixed infections. The remaining 56 were all HPV positive and were divided into two groups.Citation67 The first consisted of 25 women (44.6%) who were administered 1000 mg oral IP monotherapy thrice daily for 10 d and subjected to cervical HPV PCR after 60 d.Citation67 The second comprised 31 women (55.4%) with confirmed CIN1treated by electro-ablation plus 1000 mg oral IP monotherapy thrice daily for 10 d. They were subjected to cervical HPV PCR, PAP tests, and colposcopy after 60 d.Citation67 In the first group, clearance of cervical HPV infection was established in 17 patients (68%) and persistence in eight patients (32%). The latter were administered two additional IP courses.Citation67 Cervical HPV PCR revealed 88% clearance of cervical HPV infection after 6 mo.Citation67 In the second group, the combined treatment provided 93.5% cervical HPV clearance after 6 mo.Citation67 Hence, both the IP monotherapy and combined therapy had strong cervical HPV clearance efficacy.Citation67 Kedrova et al evaluated the efficacy of combined IP treatment in women presenting with cervical HPV16 and HPV18 infection and CIN.Citation75 After IP treatment, HPV16 and HPV18 were cleared in 77.8% and 50% of the women, respectively.Citation75 Few patients required any additional IP treatment.Citation75 In a subsequent study, 128 patients with cervical HPV infection and LSIL were divided into three groups and followed for up for 6 mo. In the first group, 48 women were treated for 28 d with six 0.500-mg IP tablets taken at 8-h intervals. In the second group, 41 women were treated with the same IP dose over a 14-d period. In the third group, 39 women were administered no IP.Citation76 After 6 mo, there was no evidence of cervical HPV infection in 93.7%,78.0%, and 43.6% of the women in the first, second, and third groups, respectively.Citation76 Based on the foregoing results, the authors recommended IP monotherapy for rapid clearance of cervical HPV infection.Citation76

In our 6-y trial, 32 women with cervical HPV infection had undergone electroconization (loop electrosurgical excision) of the uterine cervix for established HSIL and were randomly divided into two groups. In the first group, ten patients (31.2%) were not administered postoperative IP immunotherapy while the 22 patients in the second group (68.8%) did receive it. All women were subjected to cervical tests after 24 mo and 48 mo to check for HPV persistence.Citation11 The patients in the second group were administered 1 g IP thrice daily at 8-h intervals for 1 mo. For the next 5 mo, the patients were administered 500 mg IP thrice daily at 8-h intervals.Citation11 At the end of the trial, five of the patients in the first group (15.6%) presented with cervical HPV infection whereas two of the patients in the second group (6.3%) had persistent HPV infection comprising a mixture of HPV16 and other high-risk genotypes.Citation11 Three patients (9.3%) from the second group had new HPV infections consisting of different genotypes.Citation11 At the end of the study period, only four patients (12.5%) in the second group had cervical HPV infections.Citation10 Two patients (6.2%) in the second group had newly established cervical HPV infections comprising various genotypes while another two patients (6.2%) in the second group had persistent HPV infections including HPV16 and other high-risk genotypes.Citation11 By the end of the trial, there were significant differences between groups in terms of HPV incidence. Hence, long-term IP therapy reduces HSIL recurrence in HPV-positive women who have undergone surgery.Citation11 Adjuvant IP immunotherapy augmented cervical HPV infection clearance and diminished cervical dysplasia relapses in patients who were positive for cervical HPV and who underwent HSIL surgery.Citation11

Conclusion

  • Genital intraepithelial neoplasia and corresponding cancers caused by HPV are associated with high morbidity and mortality rates. Thus, ongoing research on HPV infection, epidemiology, pathogenesis, treatment, and prophylaxis is required to reduce the incidence and severity of these diseases. There is a clear relationship between HPV and human immunity, but the underlying mechanisms have not been fully elucidated.

  • The IP therapy has demonstrated good clinical efficacy in stimulating innate immunity, strengthening the host immune system, and promoting cervical HPV clearance.

  • IP therapy shows promise at lowering the recurrence of cervical dysplasia and precancers caused by chronic cervical HPV infection.

Abbreviations

CCL, chemokine ligand; CXCL, C-X-C chemokine ligand; dsRNA, double-stranded ribonucleic acid; HPV, human papillomavirus; IAD, inosine acedobendimepranol; IFN, interferon; IgA, immunoglobulin A; IgC, immunoglobulin C; IL, interleukin; IMP, intramembrane plasma particle; IP, inosine pranobex; NK, natural killer; PAMP, pathogen-associated molecular pattern; ssRNA, single-stranded ribonucleic acid; TLR, Toll-like receptor; TNF, tumor necrosis factor.

Disclosure

The author had no competing interests to declare.

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