Human-bovine Reassortant Rotavirus Research Articles

Genotype analysis of rotaviruses isolated from children during a phase III clinical trial with the hexavalent rotavirus vaccine in China

The oral hexavalent live human-bovine reassortant rotavirus vaccine (RV6) developed by Wuhan Institute of Biological Products Co., Ltd (WIBP) has finished a randomized, placebo-controlled phase III clinical trial in four provinces of China in 2021. The trail demonstrated that RV6 has a high vaccine efficacy against the prevalent strains and is safe for use in infants. During the phase III clinical trial (2019–2021), 200 rotavirus-positive fecal samples from children with RV gastroenteritis (RVGE) were further studied. Using reverse transcription-polymerase chain reaction and high-throughput sequencing, VP7 and VP4 sequences were obtained and their genetic characteristics, as well as the differences in antigenic epitopes of VP7, were analyzed in detail. Seven rotavirus genotypes were identified. The predominant rotavirus genotype was G9P [8] (77.0%), followed by prevalent strains G8P [8] (8.0%), G3P [8] (3.5%), G3P [9] (1.5%), G1P [8] (1.0%), G2P [4] (1.0%), and G4P [6] (1.0%). The amino acid sequence identities of G1, G2, G3, G4, G8, and G9 genotypes of isolates compared to the vaccine strains were 98.8%, 98.2%–99.7%, 88.4%–99.4%, 98.2%, 94.2%–100%, and 93.9%–100%, respectively. Notably, the vaccine strains exhibited high similarity in amino acid sequence, with only minor differences in antigenic epitopes compared to the Chinese endemic strains. This supports the potential application of the vaccine in preventing diseases caused by rotaviruses.

Efficacy, safety and immunogenicity of hexavalent rotavirus vaccine in Chinese infants.

A randomized, double-blind, placebo-controlled multicenter trial was conducted in healthy Chinese infants to assess the efficacy and safety of a hexavalent live human-bovine reassortant rotavirus vaccine (HRV) against rotavirus gastroenteritis (RVGE). A total of 6400 participants aged 6–12 weeks were enrolled and randomly assigned to either HRV (n ​= ​3200) or placebo (n ​= ​3200) group. All the subjects received three oral doses of vaccine four weeks apart. The vaccine efficacy (VE) against RVGE caused by rotavirus serotypes contained in HRV was evaluated from 14 days after three doses of administration up until the end of the second rotavirus season. VE against severe RVGE, VE against RVGE hospitalization caused by serotypes contained in HRV, and VE against RVGE, severe RVGE, and RVGE hospitalization caused by natural infection of any serotype of rotavirus were also investigated. All adverse events (AEs) were collected for 30 days after each dose. Serious AEs (SAEs) and intussusception cases were collected during the entire study. Our data showed that VE against RVGE caused by serotypes contained in HRV was 69.21% (95%CI: 53.31–79.69). VE against severe RVGE and RVGE hospitalization caused by serotypes contained in HRV were 91.36% (95%CI: 78.45–96.53) and 89.21% (95%CI: 64.51–96.72) respectively. VE against RVGE, severe RVGE, and RVGE hospitalization caused by natural infection of any serotype of rotavirus were 62.88% (95%CI: 49.11–72.92), 85.51% (95%CI: 72.74–92.30) and 83.68% (95%CI: 61.34–93.11). Incidences of AEs from the first dose to one month post the third dose in HRV and placebo groups were comparable. There was no significant difference in incidences of SAEs in HRV and placebo groups. This study shows that this hexavalent reassortant rotavirus vaccine is an effective, well-tolerated, and safe vaccine for Chinese infants.

Molecular and biological characterization of the human-bovine rotavirus-based reassortant rotavirus

Rotaviruses (RV) are the leading cause of acute infantile gastroenteritis, associated with elevated mortality in low-income countries. Morbidity and mortality, length and rates of hospitalization due to RV gastroenteritis are dropping. Improving the quality of newborns life is an ongoing challenge for health-care providers. In this study, homemade reassortant human-bovine rotavirus was developed and biological activity and molecular characterization of candidate vaccine were evaluated for the vaccine stability. Virus titration and purification of reassortant rotavirus strains were evaluated by plaque assays, electropherotyping. The genetic stability after first, third and sixth passage was by sequencing.Due to WHO recommendation, developingment of national capacity for vaccine production in appropriate quantities and at affordable prices is the cornerstone of developing global vaccination policies. Such studies are critical to producing national vaccines and modeling herd protection.

Safety and tolerability of a liquid bovine rotavirus pentavalent vaccine (LBRV-PV) in adults

BackgroundRotavirus Gastroenteritis (RVGE) is an important global public health problem. Recently a Lyophilized Pentavalent Human Bovine Reassortant Rotavirus vaccine (BRV-PV, Rotasiil) was licensed in India. A Liquid formulation of the same vaccine (LBRV-PV) was tested in a Phase I clinical trial. MethodsTotal 20 healthy adults were given a single oral dose of LBRV-PV and were followed for one month for safety outcomes: immediate reactions, solicited reactions, unsolicited adverse events and serious adverse events. ResultsAll 20 adults completed the study without any major protocol deviations. No immediate reaction, solicited reactions and unsolicited adverse events were reported during the study. No clinically significant changes were seen in the vital parameters and safety laboratory test results. ConclusionsLBRV-PV developed in India was safe and well tolerated in adults. Further clinical development of this vaccine in infants should be undertaken.Trial Registration – CTRI/2015/11/006,384.

Risk of Rotavirus Nosocomial Spread After Inpatient Pentavalent Rotavirus Vaccination.

Infants born prematurely or with underlying conditions are at increased risk of severe rotavirus disease and associated complications. Given the theoretical risk of nosocomial transmission of vaccine-type rotavirus, rotavirus vaccination is recommended for infants at or after discharge from neonatal care settings. Because the first dose should be administered by 104 days of age, some infants may be age-ineligible for vaccination if delayed until discharge. This prospective cohort included infants admitted to an urban academic medical center between birth and 104 days who received care in intensive care settings. Pentavalent human-bovine reassortant rotavirus vaccine (RV5) was used, per routine clinical care. Stool specimens were collected weekly (February 2013-April 2014) and analyzed for rotavirus strains using real-time reverse transcription-polymerase chain reaction. Demographic and vaccine data were collected. RV5 safety was not assessed. Of 385 study infants, 127 were age-eligible for routine vaccinations during hospitalization. At discharge, 32.7% were up-to-date for rotavirus vaccination, compared with 82.7% for other vaccinations. Of rotavirus-unvaccinated infants, 42.6% were discharged at age >104 days and thus vaccination-ineligible. Of 1192 stool specimens collected, rotavirus was detected in 13 (1.1%): 1 wild-type strain from an unvaccinated infant; 12 vaccine-type strains from 9 RV5-vaccinated infants. No vaccine-type rotavirus cases were observed among unvaccinated infants (incidence rate: 0.0 [95% confidence interval: 0.0-1.5] cases per 1000 patient days at risk). These data suggest that delaying rotavirus vaccination until discharge from the hospital could lead to missed vaccination opportunities and may be unnecessary in institutions using RV5 with comparable infection control standards.

Multivalent Rotavirus Vaccine and Wild-type Rotavirus Strain Shedding in Australian Infants: A Birth Cohort Study.

Rotavirus vaccines have reduced moderate-to-severe gastroenteritis episodes in infants and young children. Nevertheless, knowledge gaps exist concerning rotavirus vaccine shedding and vaccine impact upon mild and asymptomatic wild-type infections. Our primary objective was to investigate vaccine shedding in Australian infants where the multivalent human-bovine reassortant rotavirus vaccine, RotaTeq, was part of the routine vaccination schedule. The Observational Research in Childhood Infectious Diseases (ORChID) birth cohort study was conducted in Brisbane, Australia, from September 2010 to October 2014. Newborn infants were enrolled progressively and followed until their second birthday. Parents recorded daily symptoms and mailed weekly stool swab samples from their infants to the laboratory where reverse-transcription polymerase chain reaction testing was performed, and rotavirus-positive samples underwent genotyping to distinguish between vaccine and wild-type strains. Rotavirus was detected in 1068 of 11139 (9.6%) stool swabs from 158 infants, and 994 (93.1%) were genotyped. RotaTeq vaccine strains accounted for 951 of 994 (95.7%) typed rotavirus-positive swabs. Proportions of infants shedding RotaTeq after the first, second, and third vaccine doses were 87.0%, 57.4%, and 47.3%, respectively, and median (interquartile range) shedding duration after vaccine doses 1-3 was 3 (1-8), 1.5 (1-3), and 1 (1-2), weeks, respectively. In contrast, the incidence rate of wild-type rotavirus episodes was 10.3 (95% confidence interval, 6.8-15.6) per 100 child-years of observation. RotaTeq vaccine virus was detected in stool samples from 47%-87% of infants after each vaccine dose. Genotyping is an essential tool for differentiating between rotavirus vaccine and wild-type strains and monitoring vaccine impact in children. NCT01304914.

Efficacy and safety of a pentavalent live human-bovine reassortant rotavirus vaccine (RV5) in healthy Chinese infants: A randomized, double-blind, placebo-controlled trial.

A randomized, double-blind, placebo-controlled multicenter trial was conducted in healthy Chinese infants to assess the efficacy and safety of a pentavalent live human-bovine reassortant rotavirus vaccine (RotaTeq™, RV5) against rotavirus gastroenteritis (RVGE). 4040 participants aged 6-12weeks were enrolled and randomly assigned to either 3 oral doses of RV5 (n=2020) or placebo (n=2020), administered ∼4weeks apart. The participants also received OPV and DTaP in a concomitant or staggered fashion. The primary objective was to evaluate vaccine efficacy (VE) against naturally-occurring RVGE at least 14days following the third dose. Key secondary objectives included: VE against naturally-occurring severe RVGE and VE against severe and any-severity RVGE caused by rotavirus serotypes contained in the vaccine, occurring at least 14days after the third dose. All adverse events (AEs) were collected for 30days following each dose. Serious AEs (SAEs) and intussusception cases were collected during the entire study. (ClinicalTrials.gov registry: NCT02062385). VE against RVGE of any-severity caused by any serotype was 69.3% (95% CI: 54.5, 79.7). The secondary efficacy analysis showed an efficacy of: 78.9% (95% CI: 59.1, 90.1) against severe RVGE caused by any serotype; 69.9% (95% CI: 55.2, 80.3) and 78.9% (95% CI: 59.1, 90.1) against any-severity and severe RVGE caused by serotypes contained in the vaccine, respectively. Within 30days following any vaccination, 53.5% (1079/2015) and 53.3% (1077/2019) of participants reported at least one AE, and 5.8% (116/2015) and 5.7% (116/2019) reported SAEs in the vaccine and placebo groups, respectively. No SAEs were considered vaccine-related in recipients of RV5. Two intussusception cases were reported in recipients of RV5 who recovered after receiving treatment. Neither was considered vaccine-related. In Chinese infants, RV5 was efficacious against any-severity and severe RVGE caused by any serotype and generally well-tolerated with respect to AEs.

Identification of novel Ghanaian G8P[6] human-bovine reassortant rotavirus strain by next generation sequencing.

Group A rotaviruses (RVAs) are the most important etiological agent of acute gastroenteritis in children <5 years of age worldwide. The monovalent rotavirus vaccine Rotarix was introduced into the national Expanded Programme on Immunization (EPI) in Ghana in May 2012. However, there is a paucity of genetic and phylogenetic data on the complete genomes of human RVAs in circulation pre-vaccine introduction. The common bovine rotavirus VP7 genotype G8 has been sporadically detected in Ghanaian children, usually in combination with the VP4 genotype P[6]. To investigate the genomic constellations and phylogeny of RVA strains in circulation prior to vaccine introduction, the full genomes of two unusual G8P[6] strains, GH018-08 and GH019-08, detected during burden of disease surveillance, were characterized by Illumina MiSeq sequencing. The Ghanaian isolates, GH018-08 and GH019-08, exhibited the unusual, previously unreported genotype constellation G8-P[6]-I2-R2-C2-M2-A2-N2-T2-E2-H3. Phylogenetic analyses confirmed that 10 out of the 11 genes of GH018-08 and GH019-08 were identical/nearly identical, with significant variation detected only in their VP1 genes, and clearly established the occurrence of multiple independent interspecies transmission and reassortment events between co-circulating bovine/ovine/caprine rotaviruses and human DS-1-like RVA strains. These findings highlight the contribution of reassortment and interspecies transmission events to the high rotavirus diversity in this region of Africa, and justify the need for simultaneous monitoring of animal and human rotavirus strains.

Immunogenicity and safety of the pentavalent human-bovine (WC3) reassortant rotavirus vaccine (PRV) in Indian infants

Objective: To evaluate the immunogenicity and safety of a pentavalent rotavirus vaccine (PRV) in Indian infants.Study Design:Open-label, single-arm multicentric study.Setting:Hospital facilities (out patients)Subjects:One hundred and ten (110) healthy Indian infants were enrolled between the ages of 6 weeks and 12 weeks.Intervention:Three doses of oral pentavalent rotavirus vaccine (PRV) were administered with an interval of 4 to 10 weeks (28 to 70 days).Main Outcome Measures:Immunogenicity of PRV was based on the proportion of infants exhibiting a >3-fold rise in serum anti rotavirus IgA antibodies (from pre dose 1 to 14 days post dose 3). Safety was evaluated for 14 days after each dose. Results:Of the 110 infants enrolled, 83% exhibited at least a 3-fold rise (seroconversion) in serum anti rotavirus IgA antibodies. There were no clinically significant adverse events reported.Conclusions:A 3-dose regimen of PRV was found to be immunogenic and well tolerated in healthy Indian infants.Clinical trials registration:ClinicalTrials.gov; NCT00496054

A phase I clinical trial of a new 5-valent rotavirus vaccine

We conducted a phase I, double-blind, placebo-controlled trial to evaluate a new 5-valent oral rotavirus vaccine's safety and immunogenicity profiles. Subjects were randomly assigned to receive 3 orally administered doses of a live-attenuated human-bovine (UK) reassortant rotavirus vaccine, containing five viral antigens (G1, G2, G3, G4 and G9), or a placebo. The frequency and severity of adverse events were assessed. Immunogenicity was evaluated by the titers of anti-rotavirus IgA and the presence of neutralizing antibodies anti-rotavirus. No severe adverse events were observed. There was no difference in the frequency of mild adverse events between experimental and control groups. The proportion of seroconversion was consistently higher in the vaccine group, for all serotypes, after each one of the doses. The 5-valent vaccine has shown a good profile of safety and immunogenicity in this small sample of adult volunteers.

Vaccine-derived Human-bovine Double Reassortant Rotavirus in Infants With Acute Gastroenteritis

We describe 3 cases of acute gastroenteritis in healthy infants after vaccination with RotaTeq, shedding a G1P[8] human-bovine double reassortant rotavirus in stools. Such a double reassortant virus appears stable in vitro and may explain diarrheal symptoms in a small percentage of RotaTeq recipients, and might also be transmitted to contacts in the environment.

Efficacy of a Pentavalent Human-bovine Reassortant Rotavirus Vaccine Against Rotavirus Gastroenteritis Among American Indian Children

Before the widespread use of rotavirus vaccines, rotavirus was a leading cause of gastroenteritis among children. Navajo and White Mountain Apache children suffer a disproportionate burden of severe rotavirus disease compared with the general U.S. population. We enrolled Navajo and White Mountain Apache infants in a multicenter, double-blind, placebo-controlled trial of pentavalent human-bovine reassortant rotavirus vaccine (PRV). Subjects received 3 doses of vaccine or placebo at 4 to 10 week intervals, with the first dose given between 6 and 12 weeks of age. Gastroenteritis episodes were identified by active surveillance. Disease severity was determined by a standardized scoring system. There were 509 and 494 randomized children who received vaccine and placebo, respectively. Among placebo recipients, the incidence of rotavirus gastroenteritis was 34.2 episodes/100 child-years (95% confidence interval [95% CI]: 25.8-38.9) versus 8.1 episodes/100 child-years (95% CI: 5.4-12.5) in the vaccine group. The percentage of rotavirus episodes caused by serotypes G1, G2, and G3 was 72.3%, 23.4%, and 2.1%, respectively. There were no severe rotavirus episodes among vaccinees and 4 among placebo recipients. PRV was 77.1% (95% CI: 59.7-87.6), 89.5% (95% CI: 65.9-97.9), and 82.9% (95% CI: 61.1-93.6) effective against G1-G4 rotavirus disease, severe and moderate rotavirus disease combined, and outpatient visits for rotavirus disease, respectively. The risk of adverse events was similar for the vaccine and placebo groups. PRV was highly effective in preventing rotavirus disease and related health care utilization in these American Indian infants. Vaccine efficacy and immunogenicity were similar to the overall study population enrolled in the multicenter trial.

Chronic Rotavirus Infection in an Infant with Severe Combined Immunodeficiency: Successful Treatment by Hematopoietic Stem Cell Transplantation

Kobrynski et al. [1] showed gastrointestinal complaints in children can be an early sign of primary immunodeficiency disease (PIDD). Rotavirus infection associated with PIDD can be life-threatening. Rotavirus is a leading cause of childhood gastrointestinal disease worldwide [2]. Most rotavirus disease is caused by 5 G types (G1-G4 and G9) and 3 P types (P1A[8], P1B[4], and P2A[6]) [2]. Two live oral rotavirus vaccines, RotaTeq® (5 different human-bovine reassortant rotavirus strains; Merck and Co, Whitehouse Station, NJ) and Rotarix® (1 human rotavirus strain; GlaxoSmithKline, Rixensart, Belgium) are recommended for routine immunization of US infants [2]. Disease caused by emerging worldwide rotavirus type, G9P[8] may be prevented by both vaccines although this strain is not included in either vaccine. Severe combined immunodeficiency (SCID) is characterized by lack of T cells and life-threatening infections [3]. Treatment of viral infections prior to hematopoietic stem cell transplantation (HSCT) with intravenous immunoglobulin (IVIG) and antivirals has been attempted, but persistence of viral disease has been reported [3–8]. We report a 7 month-old male infant with SCID who had persistent, nonvaccine-associated rotavirus gastroenteritis and viremia despite oral and IVIG administration. T-cell engraftment following HSCT possibly helped by oral and IVIG was necessary to eliminate rotavirus infection. The full-term, formula-fed infant received RotaTeq at 2 and 4 months of age. The patient developed chronic intermittent diarrhea at 2 months of age and was hospitalized at 7 months of age with respiratory distress, diarrhea, and failure to thrive. A peripheral white blood cell count was 16,140 cells/μl with 59% neutrophils, 17% lymphocytes (absolute lymphocyte count=2743cells/μl [normal range 3,900–9,000]), 7% monocytes, and 13% eosinophils. Bronchoscopy aspirate revealed Pneumocystis jiroveci. Stool for rotavirus was positive by electron microscopy (EM). Immunoglobulins were very low including IgG 77 mg/dL (normal range 184–974 mg/dL), IgA <6 mg/dL (normal range 9–107 mg/dL), and IgM 36 mg/dL (normal range 41–197 mg/dL). The CD3+T cells were severely low (32 cells/mm3, normal range 1919–5054 cells/mm3), CD19+B cells were elevated (2715 cells/mm3, normal range 566–2535 cells/mm3), and CD3−CD56+CD16+NK cells were low (28 cells/mm3, normal range 181–901 cells/mm3). T-cell proliferation to mitogens was markedly depressed. A hemizygous mutation (nucleotide substitution A for G at position 1451 in the polyA tail region) was present in the common gamma chain of interleukin-2 receptor consistent with X-linked SCID. Multipe doses of IVIG (Gamunex®, Talecris) were given before and after transplantation, including two doses of 300 mg/kg administered orally at 8 months of age (Fig. 1). Molecular analysis of stool and serum specimens identified a non-vaccine associated human rotavirus strain G9P[8]. The patient received a 10/10 matched unrelated donor unfractionated HSCT with pretransplant myeloablative conditioning at 9.5 months of age. Rotavirus-positive diarrhea persisted until 2 months post transplant (age 11.5 months), coincident with T-cell engraftment (Fig. 1). The patient, last tested at 14.5 months of age, had no detectable rotavirus. Figure 1 The detection of rotavirus in relation to the presence of CD3+,CD4+, and CD8+T-cell quantification before and after bone marrow transplantation. *=CD3+T cells were 100% donor origin calculated by short tandem repeat studies; ¥=Several serum samples ... Reverse transcriptase polymerase chain reaction (RT-PCR) using rotavirus gene 9 and gene 4 primer sets resulted in cDNA products from stool and serum samples. Homology of gene 9 and gene 4 amplicon sequences to GenBank database sequences confirmed the patient’s stools contained rotavirus strain G9P[8]. There was 98% nucleotide homology between the stool rotavirus gene 4 sequence, which comprised 51% of the 2328 nt ORF, and two fully-sequenced P[8] rotaviruses but no significant homology with a partial RotaTeq vaccine gene 4 sequence. There was 98% nucleotide homology between the stool rotavirus gene 9 sequence, which comprised 85% of the 978 nt ORF, and two fully-sequenced G9 rotaviruses. There was a single nucleotide change in gene 9 (residue 595 C→T, resulting in a silent mutation) between two stools obtained 74 days apart. There was no change in gene 4 sequence between stools obtained 54 days apart. Neutralizing antibodies to rotavirus G9 were present in the orally administered immunoglobulin product at a concentration of 1:1600. Neutralizing antibodies to serotypes G1(WA, 1:800; K8, 1:1600) and G3 (SA11, 1:3200) were present at similar concentrations. CD3+T cells were very low (32 cells/ml, normal range 2500–6500 cells/ml) prior to transplantation (Fig. 1). Rotavirus became undetectable by EM two months post transplantation with CD3+, CD4+, and CD8+T-cell engraftment as shown by return of lymphocytes by 65 days post transplantation (CD3+T cells=138/mm3 at 2 months post transplantation). T-cell proliferation, as assessed by response to mitogens, was <3% of normal range and became present at five months post transplantation (data not shown). Chimerism analysis showed presence of donor T cells (100%) and absence of donor B cells (0%) at two and seven months post transplantation.

Lessons From the US Rotavirus Vaccination Program

EVERY WINTER, CHILDREN, PARENTS, AND CLINICIANS IN the United States have to deal with the annual seasonal outbreak of rotavirus, the most common cause of severe diarrhea in children worldwide. Before the implementation of routine vaccination against rotavirus in 2006, most US children had experienced an episode of rotavirus diarrhea by the age of 5 years, an estimated 400 000, or 1 child in 6, required outpatient treatment and about 55 000 to 70 000 children, or 1 in 50, were hospitalized. The health consequences of this annual event in the United States were unsettling and were estimated to cost more than $1 billion per year. When the first new rotavirus vaccine was licensed in 2006, uncertainty existed about whether parents would agree to have their infants immunized and whether clinicians would actively promote its use. Rotavirus vaccines had been severely stigmatized in 1999 when an earlier vaccine, tetravalent rhesus-human reassortant vaccine (RotaShield, Wyeth Laboratories) was abruptly removed from the market because of its link with intussusception, an uncommon form of intestinal obstruction. To assess whether the next generation of rotavirus vaccines harbored the same complication, the US Food and Drug Administration (FDA) required manufacturers to enroll and follow up more than 60 000 infants in clinical trials. Merck and GlaxoSmithKline set off cautiously to conduct multicenter trials of the pentavalent human-bovine WC3 reassortant rotavirus vaccine (RotaTeq, Merck & Co) and the RIX4144 strain human rotavirus vaccine (Rotarix, GlaxoSmithKline Biologicals), ultimately recruiting more than 70 000 infants each, some of the largest and most costly licensure trials ever conducted. Neither vaccine was associated with intussusception in these trials. Over the past 4 years, uptake of the new vaccines has been remarkable. In the United States, the vaccines are expensive, about $200 for the series, but this hurdle of cost was addressed in part by Centers for Disease Control and Prevention’s (CDC’s) Vaccines for Children Program, a federally funded program that provides vaccines at no cost to those unable to pay. By 2010, nearly 60% of US children aged 19 to 35 months were immunized against rotavirus. Because rotavirus diarrhea affects children in the first 5 years of life, it may soon be possible to evaluate the full benefit of the vaccine. For the past decade, the CDC has monitored rotavirus activity in the United States from laboratories that document weekly the number of fecal specimens from children seeking care for diarrhea and the percentage of these specimens that test positive for rotavirus. In 2008, the effects of the rotavirus immunization program were first noted from this surveillance program when the number of rotavirus detections decreased by 64%; these declines have been sustained through 2010. Reports assessing discharge data from hospitals around the country noted that hospitalizations for acute gastroenteritis declined by 45% during the 2008 winter rotavirus season, averting approximately 50 000 hospitalizations nationwide. An unanticipated finding was that hospital admissions for diarrhea also declined among unvaccinated individuals aged 5 through 24 years, suggesting that the vaccine was having a herd effect, perhaps by preventing rotavirus transmission from a younger immunized cohort. More recently, a series of independent regional studies have documented excellent performance of the vaccine against rotavirus disease and documented an 85% to 90% reduction in hospital discharges and visits to emergency departments. Previously, diarrheal illnesses were reported on 10% to 12% of all hospital discharge records for children younger than 5 years, and surveillance indicated that rotavirus accounted for about 40% to 50% of these events. Consequently, an 85% to 90% reduction in this disease from vaccination should lead to a 4% to 6% reduction in total hospitalizations for children younger than 5 years with the commensurate savings in hospital and indirect costs. The introduction of rotavirus vaccines has not been without challenges. In 2010, the identification of porcine circovirus (PCV) in Rotarix led to a temporary suspension of this vaccine; PCV genetic material was also later identified in RotaTeq. More recently, both Rotarix and RotaTeq have been associated with a low-level but elevated risk of intussusception—about 5to 10-fold lower than that seen

Development, clinical evaluation, and post‐licensure impact of RotaTeq, a pentavalent rotavirus vaccine

Rotavirus gastroenteritis (RVGE) is the leading cause of severe diarrhea in children worldwide. This paper provides an overview of the development, clinical evaluation, and postlicensure impact of RotaTeq™(Rotavirus Vaccine, Live, Oral, Pentavalent, Merck & Co., Inc.). RotaTeq, an oral vaccine, is uniquely designed to contain five human-bovine reassortant rotavirus strains expressing the human serotypes G1, G2, G3, G4, and P1A[8], which represent the most common human rotavirus serotypes responsible for ∼85% of RVGE worldwide. The development required novel solutions for manufacturing, testing, and formulation for each of the reassortants. In one of the largest vaccine clinical trials conducted, the vaccine was shown to be well tolerated and highly efficacious against severe RVGE. Efficacy has also been demonstrated in lower-income countries. In large U.S. postlicensure studies, there have been no safety signals identified, and RotaTeq has had a significant impact on reducing RVGE and its associated medical costs since licensure in 2006.

Cost-effectiveness of a pentavalent human–bovine reassortant rotavirus vaccine for children ≤5 years of age in Taiwan

Objective:A Markov model was used to assess the impact of RV5, a pentavalent (G1, G2, G3, G4, P1A[8]) human bovine (WC3 strain) reassortant rotavirus vaccine, on reducing the healthcare burden and cost associated with rotavirus gastroenteritis (RGE) in Taiwan. Other cost-effectiveness analyses for rotavirus vaccination in industrialized countries have produced varying results depending on the input parameters assumed.Methods:Vaccination with RV5 is compared to no vaccination in a hypothetical cohort of Taiwanese children during their first 5 years of life to determine the per dose prices at which vaccination would be cost neutral or provide good value based on established standards from the healthcare (direct medical care costs only) and societal (all RGE-related costs) perspectives. The effects of vaccination on RGE healthcare utilization and days of parental work loss missed are based on results from the Rotavirus Efficacy and Safety Trial.Results:Without vaccination there would be 122,526 symptomatic episodes of RGE. Universal vaccination would reduce RGE-related deaths, hospitalizations, emergency department, and outpatient visits by 91.7%, 92.1%, 83.7%, and 73.4%, respectively. The price per dose at which vaccination would be cost-neutral is US$ 21.80 (688 NTD) and US$ 26.20 (827 NTD) from the healthcare and societal perspectives, respectively. At $25 per dose, the cost per QALY gained is US$ 2261 (71,335 NTD) from the healthcare perspective and cost saving from the societal perspective.Key limitations:The model only assesses the effect of RV5 on vaccinated children and does not account for herd immunity. However, given that high levels of coverage are anticipated in Taiwan, the effects of herd immunity are likely to be short-term.Conclusion:A pentavalent rotavirus vaccination program is likely to substantially reduce the healthcare burden associated with rotavirus gastroenteritis at a cost per QALY ratio within the range defined as cost-effective.

Spotlight on Pentavalent Rotavirus Vaccine (RotaTeq®) in the Prevention of Rotavirus Gastroenteritis in Europe†

In Europe, rotavirus gastroenteritis is associated with a significant health, economic, and social burden, as it is responsible for large numbers of hospitalizations and other healthcare encounters among infants and children, as well as numerous days of work lost by parents and caregivers. RotaTeq is a three-dose, orally administered, live, pentavalent human-bovine reassortant rotavirus vaccine used for the active immunization of infants for prevention of rotavirus gastroenteritis. The protective efficacy of RotaTeq has been evaluated in terms of its effects on the incidence of rotavirus gastroenteritis and on healthcare resource use. Clinical trial data from REST (a randomized, double-blind, placebo-controlled, multinational study in ≈70 000 healthy infants aged 6-12 weeks) and various subgroup analyses, including a large European cohort, have shown that RotaTeq may be administered at the same time as various other routine vaccines, has high and sustained efficacy covering the main period of risk for rotavirus gastroenteritis, has early protective efficacy after the first and second doses, reduces rotavirus gastroenteritis-associated hospitalization and emergency department and physician visits, and is generally well tolerated. Moreover, RotaTeq has demonstrated efficacy against the five most prevalent serotypes of rotavirus in Europe (G1-G4, G9), in terms of reductions in associated healthcare resource use. There is also evidence that the widespread use of RotaTeq may provide herd immunity, as it appears to have indirect benefits in older, unvaccinated children. Reports on the 'real world' effectiveness of RotaTeq in Europe are just emerging, but data from the US have shown a rapid and marked reduction in rotavirus burden nationwide during the ≈2-year period following the introduction of RotaTeq and the subsequent availability of official recommendations advocating universal use of the vaccine as part of routine childhood immunization. Postmarketing surveillance data from the US have not identified any concerns, such as an association with intussusception or Kawasaki disease, related to the safety of RotaTeq. In conclusion, RotaTeq is a generally well tolerated vaccine that has efficacy against the five most prevalent serotypes of rotavirus in Europe and provides sustained efficacy over the main risk period for rotavirus gastroenteritis in infants and children, reducing hospitalizations and emergency department visits by decreasing the incidence and severity of illness.

RotaTeq: Progress toward Developing World Access

Phase III studies of an oral, live, pentavalent, human-bovine reassortant rotavirus vaccine (RotaTeq; Merck) in developed countries have demonstrated that it is well tolerated with regard to intussusception and other adverse events and is efficacious in preventing rotavirus gastroenteritis and associated healthcare encounters. However, it cannot be assumed that rotavirus vaccines will be equally efficacious in infants and young children in the developing world. Differences in host populations, associated health conditions, and the epidemiology of rotavirus disease could affect vaccine performance. Concern about the potential for differences in efficacy stems from studies of previous candidate rotavirus vaccines, including bovine and rhesus rotaviruses, which showed no or variable efficacy in developing regions. Given this history, the World Health Organization (WHO) recommended that the efficacy of "new" rotavirus vaccines should be demonstrated in diverse geographic areas, including developing countries, before widespread implementation. Successful implementation of any rotavirus vaccine in the developing world requires additional clinical research and sharing of early introduction experiences. We discuss efforts to bring RotaTeq vaccine to the developing world. Critical steps to achieve this goal include the clinical evaluation of vaccine safety and efficacy in a multisite trial in Asia and Africa, evaluation of concomitant use with other pediatric vaccines routinely used, and vaccine assessment in special populations (premature, human immunodeficiency virus-infected, and malnourished infants). Completion of WHO prequalification of RotaTeq and affordability are also key requirements to routine vaccine introduction. The RotaTeq Partnership with the Nicaraguan Ministry of Health provides an example of the successful introduction of this vaccine into a developing world country.

Rotavirus Infections and Vaccines

Rotaviruses are the most common cause of severe gastroenteritis in children. By 5 years of age virtually every child worldwide will have experienced at least one rotavirus infection. This leads to an enormous disease burden, where every minute a child dies because of rotavirus infection and another four are hospitalized, at an annual societal cost in 2007 of $US2 billion. Most of the annual 527 000 deaths are in malnourished infants living in rural regions of low and middle income countries. In contrast, most measurable costs arise from medical expenses and lost parental wages in high income countries. Vaccines are the only public health prevention strategy likely to control rotavirus disease. They were developed to mimic the immunity following natural rotavirus infection that confers protection against severe gastroenteritis and consequently reduces the risk of primary healthcare utilization, hospitalization and death. The two currently licensed vaccines--one a single human strain rotavirus vaccine, the other a multiple strain human-bovine pentavalent reassortant rotavirus vaccine--are administered to infants in a two- or three-dose course, respectively, with the first dose given at 6-14 weeks of age. In various settings they are safe, immunogenic and efficacious against many different rotavirus genotypes. In high and middle income countries, rotavirus vaccines confer 85-100% protection against severe disease, while in low income regions of Africa and Asia, protection is less, at 46-77%. Despite this reduced efficacy in low income countries, the high burden of diarrheal disease in these regions means that proportionately more severe cases are prevented by vaccination than elsewhere. Post-licensure effectiveness studies show that rotavirus vaccines not only reduce rotavirus activity in infancy but they also decrease rates of rotavirus diarrhea in older and unimmunized children. A successful rotavirus vaccination program will rely upon sustained vaccine efficacy against diverse and evolving rotavirus strains and efficient vaccine delivery systems. The potential introduction of rotavirus vaccines into the world's poorest countries with the greatest rates of rotavirus-related mortality is expected to be very cost effective, while rotavirus vaccines should also be cost effective by international standards when incorporated into developed countries immunization schedules. Nonetheless, cost effectiveness in each country still depends largely on the local rotavirus mortality rate and the price of the vaccine in relation to the per capita gross domestic product.

Prevention of rotavirus gastroenteritis in infants and children: rotavirus vaccine safety, efficacy, and potential impact of vaccines

Rotavirus infection is the most common cause of severe gastroenteritis globally, with greater than 86% of deaths occurring in low-income and middle-income countries. There are two rotavirus vaccines currently licensed in the United States and prequalified by the World Health Organization. RV1 is a monovalent attenuated human rotavirus strain, given orally in two doses. RV5 is a pentavalent human-bovine reassortant rotavirus vaccine, given orally in three doses. A third rotavirus vaccine, LLV, is a lamb rotavirus strain given orally as a single dose, which is currently available only in China. RV1 and RV5 have been shown to be highly efficacious in developed countries, and initial results from trials in Africa and Asia are promising as well. At least three other vaccines are in development, which are being developed by manufacturers of developing countries. Further studies are needed to clarify issues including administration of oral rotavirus vaccines with breastfeeding and other oral vaccines, and alterations in dosing schedule. Using new data on global diarrheal burden, rotavirus is estimated to cause 390,000 deaths in children younger than 5 years. Should rotavirus vaccines be introduced in the routine immunization programs of all countries, a potential of 170,000 deaths could be prevented annually. The largest impact on mortality would be seen in low-income and middle-income countries, despite poor immunization coverage and lower efficacy. Therefore, international efforts are needed to ensure that rotavirus vaccines reach the populations with highest burden of rotavirus disease.