key: cord-011486-5osu6hdu
authors: Lestari, Fajar Budi; Vongpunsawad, Sompong; Wanlapakorn, Nasamon; Poovorawan, Yong
title: Rotavirus infection in children in Southeast Asia 2008–2018: disease burden, genotype distribution, seasonality, and vaccination
date: 2020-05-21
journal: J Biomed Sci
DOI: 10.1186/s12929-020-00649-8
sha: 
doc_id: 11486
cord_uid: 5osu6hdu

BACKGROUND: Rotaviruses (RVs) are recognized as a major cause of acute gastroenteritis (AGE) in infants and young children worldwide. Here we summarize the virology, disease burden, prevalence, distribution of genotypes and seasonality of RVs, and the current status of RV vaccination in Southeast Asia (Cambodia, Indonesia, Lao People’s Democratic Republic, Malaysia, Myanmar, Philippines, Singapore, Thailand, and Vietnam) from 2008 to 2018. METHODS: Rotavirus infection in Children in Southeast Asia countries was assessed using data from Pubmed and Google Scholars. Most countries in Southeast Asia have not yet introduced national RV vaccination programs. We exclude Brunei Darussalam, and Timor Leste because there were no eligible studies identified during that time. RESULTS: According to the 2008–2018 RV surveillance data for Southeast Asia, 40.78% of all diarrheal disease in children were caused by RV infection, which is still a major cause of morbidity and mortality in children under 5 years old in Southeast Asia. Mortality was inversely related to socioeconomic status. The most predominant genotype distribution of RV changed from G1P[8] and G2P[4] into the rare and unusual genotypes G3P[8], G8P[8], and G9P[8]. Although the predominat strain has changed, but the seasonality of RV infection remains unchanged. One of the best strategies for decreasing the global burden of the disease is the development and implementation of effective vaccines. CONCLUSIONS: The most predominant genotype distribution of RV was changed time by time. Rotavirus vaccine is highly cost effective in Southeast Asian countries because the ratio between cost per disability-adjusted life years (DALY) averted and gross domestic product (GDP) per capita is less than one. These data are important for healthcare practitioners and officials to make appropriate policies and recommendations about RV vaccination.

RV was first identified in cattle in 1969 [1] . The virus appeared similar to those that cause diarrhea in mice [2] , calves [3] , and a virus identified from a rectal swab of a healthy monkey [4] . In May 1973, Bishop, Davidson, Holmes, and Ruck examined ultrathin sections of duodenal mucosa from children with acute gastroenteritis (AGE) by electron microscopy (EM), and found abundant viral particles in the epithelial cell linings of the upper villous surface which were similar in appearance to the RVs discovered in animals before [5] . EM also revealed 70-nm particles in negatively stained fecal extracts [6, 7] . The viral particle was initially identified by several names including reovirus-like, orbivirus-like, duovirus, infantile gastroenteritis virus, or a "new" virus.

The wheel-like structure observed on EM eventually led to the naming concensus of Rotavirus (rota is Latin for wheel) [8] . RVs have now been shown to be a cause of diarrhea in the young of many mammalian and avian species [9] .

RVs are 70-nm, non-enveloped RNA viruses belonging to the family Reoviridae. The RV genome consists of 11 segments of double-stranded RNA (dsRNA) surrounded by a triple-layered capsid. Each genomic fragment encodes protein of different function. The outer layer proteins (viral protein [VP] 4 and VP7) mediate attachment and penetration; the inner layer is composed of VP2 protein and encloses the viral genome and the minor protein VP1, the viral RNA-dependent RNA polymerase, and VP3, the viral capping enzyme. The middle layer is composed of VP6 which interacts with and stabilized the inner and outer layer [9] . VP6 defines species/group and subgroup specificities [10] [11] [12] . All RNA segments, except for segment 11, are monocistronic, encoding either structural viral proteins (VP1 to VP4, VP6, and VP7) or non-structural proteins (NSP1 to NSP5). Genome segment 11 codes for two proteins: NSP5 and NSP6 [9] . RVs can be differentiated by a dual classification system, based on the two outer capsid proteins, VP7 and VP4, that determine the G (VP7, glycoprotein) and P (VP4, protease-sensitive) genotypes [13] . At least 36 G types and 51 P types have so far been identified in humans and animals [14] .

A whole genome-based genotyping system was recently proposed for RV Group A (RVA) based on the genotype assignment of all 11 gene segments [15] . The genome of individual RV strains is given the complete descriptor of Gx-P [x]-Ix-Rx-Cx-Mx-Ax-Nx-Tx-Ex-Hx to identify the genotypes of the VP7-VP4-VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5/6 encoding RNA segments, respectively. Most strains demonstrate either a Wa-like (G1-P [8] -I1-R1-C1-M1-A1-N1-T1-E1-H1), DS-1 (G2-P[4]-I2-R2-C2-M2-A2-N2-T2-E2-H2), or AU-1-related (G3-P[3]-I3-R3-C3-M3-A3/A12-N3-T3-E3-H3/H6) genotype constellation [16, 17] .

Indirect immunofluorescence techniques targeting VP6 are used to differentiate RV species. RVs are currently differentiated into at least nine species, designated A to I and a tentative tenth species, J. RVA infects in birds and mammals; RVB, RVC, RVE, RVH, and RVI have been detected in one or more mammalian hosts; RVD, RVF, and RVG have been detected only in birds; RVJ infects bats [18] [19] [20] . Table 1 shows rotavirus groups and its host.

RVs were recognized as a major cause of AGE in infants and young children in 1973 [2, 7] . RV is the leading cause of diarrhea-associated mortality among children younger than 5 years, although the burden of RV has decreased during the past decade. RV infections were responsible for approximately 128,515 deaths annually among children younger than 5 years. RV constitutes 1 of the 13 diarrhea etiologic agents measured in the 2016 Global Burden of Disease Study [37] . It is the most prevalent agent causing severe diarrhea in both developed and developing countries [38, 39] . After RV vaccine introduction in developed countries, norovirus become the predominant viral pathogen that caused AGE in children. Norovirus prevalence remained stable or increased, whereas rotavirus activity dramatically decreased [40] [41] [42] . Nevertheles, from 2000 to 2013 in Southeast Asia, [25, 32] approximately 50.7% (n = 10,765) of total diarrhea mortality was associated with RV disease [43] . Figure 1 shows the prevalence and death caused by diarrheal disease and RV in children under 5 years old from 1990 to 2017 in Southeast Asia. The prevalence of diarrheal diseases in Southeast Asia countries varies, but the mortality trend associated with diarrhea and especially RV infection has been decreasing in recent years. Lao People's Democratic Republic [PDR] reports one of the highest death rates in this period. However, improvement in hygiene and sanitation combined with the introduction of the rotavirus vaccine has contributed to decreasing RV infection [46] .

We collected RV surveillance data from 9 countries in Southeast Asia (Cambodia, Indonesia, Lao PDR, Malaysia, Myanmar, Philippines, Singapore, Thailand, and Vietnam) for the years 2008-2018 to estimate the proportion of RV gastroenteritis (RVGE) ( Table 2) . A total of 52,579 stool samples were collected of which 21, 444 (40.78%) were RV positive. Acute diarrheal disease caused by RV is still a major cause of morbidity and mortality in children under 5 years old in developing countries, which may be attributed to the regions' lower standards of living and hygiene conditions [46] . However, our study revealed that as the gross domestic product (GDP) per capita increases, and the economic status of Southeast Asian countries improves, the RV mortality rate steadily declines (Fig. 2 ). Higher socioeconomic status (SES) can improve sanitation, hygiene practices, and healthcare facilities to support better living conditions and decrease the RV mortality in children.

Among the data from Southeast Asia countries examined, the most predominant genotype distribution of RV has changed except in Lao PDR and Malaysia. In 2009-2013, G1P [8] and G2P [4] were the most predominant genotypes, but starting 2014, it changed into the rare and unusual genotypes G3P [8] , G8P [8] , and G9P [8] . Several uncommon RV genotypes such as G2P [8] , G8P [6] , G5P [19] , G9P [4] , G9P [6] , and G1P7 [5] were identified in the surveillance data. The presence of such diversity among RV isolates provides insight into the evolution of these strains, which can arise due to point mutations, genetic rearrangements, reassortment events, and interspecies transmission [13, 80, 81] . Circulating RV strain appears diverse despite RV vaccination, which may enable the increase in the prevalence of non-vaccine strains. Thus, the circulation of strains in which vaccines have lower efficacy eventually impairs vaccine effectiveness [82] . In the Philippines, where the Rotarix® vaccine was introduced in July 2012, the frequency of RVGE cases caused by G1P [8] decreased while the circulation of G9P [8] increased significantly [83] . The genotype distribution of RV in Southeast Asia is shown in Table 3 .

Differences in the predominance of RV genotypes and newly emerging strains were identified over the surveillance period in Cambodia. The G1P [8] genotype was predominant in 2010, 2011, and 2012 (74, 66, and 79%, respectively), whereas genotype G2P [4] predominated between 2013 (54%) and 2014 (44%). The previously uncommon strain G8P [8] also emerged in 2014 (21%). The proportion of G8P [8] genotype detections increased further in 2015 (41%), in conjunction with the emergence of G9P [8] (10%). By 2016, the detection of genotype G9P [8] had increased to 18%, and G3P [8] became the most prevalent genotype (responsible for 63% of detections) [47] .

In Indonesia, the surveillance results demonstrated a changing trend for the most prevalent genotype, from G1P [8] in 2009-2013 to G3P [8] in 2014-2018. From 2009-to 2013, G1P [8] was the most prevalent genotype circulating, which accounted for 38, 73.7, 67.5, 85.7, and 60.1% each year, respectively. G3P [8] became the most predominant strain in 2013, and this continued to 2015, accounting for 49,7, 82.5%, and 84,4%, respectively [49, 53, [55] [56] [57] . Another study reported that G3P[8]/ [6] was also the predominant strain during 2015-2018 [58] .

During the 7-year surveillance period in Lao PDR, the most predominant genotypes identified by year were G2P [4] (40%) and G1P [8] (32%) in 2009; G2P [4] (28%) and G9P [8] (26%) in 2010; G3P [8] (61%) and G1P [8] (36%) in 2011; G3P [8] (81%) in 2012; G1P [8] (57%) and G2P [4] (34%) in 2013; G2P [4] (81%) in 2014; and G1P [8] (96%) in 2015 [59] .

From 2008 to 2010, the most common genotype in Malaysia was G1P [8] (82%). Other genotypes identified were G2P[4] (7.6%) and G9P[8] (6.3%). Approximately 4% of the samples were either mixed or untypeable (G12P [8] , G3P [9] , G9P [9] , G3P [8] ) [60] . A 2006 preliminary report in Sabah State showed that approximately 33% of samples were positive for RV, of which 33% were of genotype G4P [9, 84] .

In Myanmar, the most common strains in 2009 were G1P [8] (28.3%) and G12P [8] (28.3%). G12P [8] was detected from 2009 to 2012, ranging from 28.3% in 2009 to 70% in 2011. G2P [4] became the most predominant strain in 2012-2013, followed by G1P [8] in 2013-2014. G9P [8] comprised only 1% of the RV strains in 2011 and increased to 97.5% in 2014. While in 2015, the majority (90%) of RV strains comprised G9P [8] (54%) and G3P [8] (36%). G9P [8] emerged in Myanmar in 2011 and was the most common strain in 2014 and 2015 [61, 85] .

In the Philippines, 1949 (98.5%) RVA-positive stool specimens were successfully typed. The most common genotypes identified were G1P [8] and two G9P [4] strains. Also, animal strains were detected in specimens from 10 children, including 1 G3P [9] felinelike and nine G4P [6] porcine-like strains [63] . The predominant strain observed in Singapore was G1P[8] (18,3%), while G9P[8] (9,9%) was the second most common type observed among children in Singapore [65, 66] .

In Thailand, G2P [4] was the most common genotype in 2008 (53,5%). G1P [8] strains were G3P [8] . Uncommon genotypes found were G1P7 [5] , G5P [19] , G9P [4] , and G9P [6] , adding to the existing list of uncommon genotypes reported to circulate in Thailand [67] [68] [69] [70] [71] [73] [74] [75] [76] . Based on RV diarrhea data from four sentinel hospitals in Vietnam from 2012 to 2015, G1P [8] was the most prevalent strain during 2012 and 2013, accounting for 80 and 82% of total genotyped samples, respectively. G2P [4] was found in 5% of samples in 2012 and 9% in 2013. In 2014 and 2015, the proportion of RVGE caused by G2P [4] increased to 36 and 28%, respectively. G8P [8] was not detected in 2012 and 2013, it accounted for only 1% of specimens in 2014, and it became predominant (31%) in 2015 [78] .

Meteorological conditions have an indirect yet important impact on the epidemiology of human rotavirus infection. Weather-related low indoor relative humidity and indoor crowding may be key factors in the epidemiology of rotavirus disease. Hospitalizations for rotavirus gastroenteritis tended to be more common after a cold or dry month than after a warm or wet corresponding calendar month [86] .

The temporal trend of Cambodian RV infection shows substantial year-round transmission with prominent peaks during colder, dry months. Peaks typically occurred between November and May [47] . In Indonesia, RV infection was present throughout the year and did not demonstrate clear annual seasonality [55] . Conversely, infection generally peaks during the rainy season in Singapore and Malaysia. An outbreak of RV infection was observed from January to March [65, 87] . Positive RV cases increased in number and proportion during the dry season (January-April) each year in Lao PDR [88] . In Myanmar and the Philippines, RV infection has a strong seasonal peak in colder, drier months, as seen in other Asian countries. The highest rate of RV infection occurred in January and February [61, 63] . RV cases in Thailand were most prevalent during the cooler months, specifically from January to March, but RV was detected every month in the northern part of Thailand, where the weather is relatively cooler compared to the rest of the country [68] . In Vietnam, RV was detected every month, but most RV gastroenteritis (GE) cases occurred between December and May [78] . Figure 3 shows the RV seasonality in Southeast Asian countries.

The seasonal pattern in RV varies by climatic region and is also associated with local weather. A reduction in RV rates was associated with increased temperature and precipitation [89] . There is a significant association between increased numbers of estimated positive RV cases and lower humidity, rain, and temperature. In children younger than 2 years old, RV was the pathogen most frequently identified in the winter, dry, or cool/dry seasons [90] . In tropical climates, the higher temperature was associated with a greater decrease in RV than in humid mid-latitude climates [91] . It had been suggested that the seasonal pattern may be driven by airborne transmission of the disease [92] .

One of the best strategies for decreasing the global burden of disease is the development and implementation of effective vaccines [43] . RV is the most common cause of vaccine-preventable severe diarrhea [93] . The World Health Organization (WHO) recommended that RV vaccines be included in immunization programs in the European region and the Americas in 2006. In 2009, following efficacy studies in low-income countries (LICs) and lower-middle-income countries (LMICs) in Africa and Asia, the WHO recommended the use of RV vaccines in all National Immunization Programs (NIPs) [94] . RV vaccines had been introduced in 101 countries by the end of 2018, and global coverage was estimated to be at 35% [95] . Most countries in Southeast Asia have not yet introduced national RV vaccination programs. Among Asian countries, only the Philippines, and recently Thailand have introduced the vaccines on a limited basis [96] . The Global Alliance for Vaccines and Immunizations (GAVI), also known as the Vaccine Alliance, actively supports RV vaccination by subsidizing the cost in eligible countries. In LMIC, the budget impact is an important criterion for funding new interventions, particularly for large public health investments such as new vaccines. By the end of 2018, GAVI had funded RV vaccine introductions in 45 countries [97] .

Research to develop a safe, effective RV vaccine began in the mid-1970s when investigators demonstrated that previous infection with animal RV strains protected laboratory animals from experimental infection with human RVs [98] . The first multivalent live oral reassortant vaccine developed was RotaShield® (a rhesus RV tetravalent [RRV-TV] vaccine) in the late 1980s [99] . The RRV-TV vaccine was licensed in August 1998 for routine use in children in the United States at 2, 4, and 6 months of age due to its proven efficacy [100] . In 1999, RotaShield® was voluntarily withdrawn from the U.S. market due to an increased risk of intussusception within 3 to 14 days after the first dose in infants < 3 months of age [101] .

Due to the past association of intussusception and the earlier RV vaccine, large safety studies were performed both for RV1 and RV5 before market authorization [102] . Rotarix® vaccine were highly efficacious in protecting infants against severe rotavirus gastroenteritis [66, 103] and were not associated with an increased risk of intussusception [104] [105] [106] . The pentavalent rotavirus vaccine (RotaTeq®) was highly efficacious against severe rotavirus gastroenteritis and provided substantial protection against rotavirus gastroenteritis of any severity. A significantly increased risk of intussusception in vaccine recipients was not detected [107] . In February 2014, WHO reviewed global intussusception data and found that the risk of intussusception following current rotavirus vaccines remains small compared to the benefits of preventing the impact of severe diarrhea [108] . At the end of 2018 there are four globally available WHO-prequalified oral vaccines (Rotarix® and RotaTeq®, Rotavac® and Rotasiil®) [109] , one rotavirus vaccine licensed in China (Lanzhou lamb RV vaccine), one in Vietnam (Rotavin-M1), and there are several candidates in development [110] .

Two RV vaccines, Rotarix® and RotaTeq®, have been developed by Glaxo Smith Kline and Merck, respectively. Rotarix® is a live attenuated monovalent vaccine derived from the most common human RV strain, G1P [8] . Rota-Teq® is a live attenuated pentavalent vaccine containing mono-reassortant strains with genes encoding the human G1, G2, G3, G4, and P [8] protein in the genetic background of a bovine RV strains [39, 100] . These vaccines are highly effective for the global prevention of severe diarrhea and are included in the NIPs or phased subnational introductions in 101 countries by the end of 2018 [95, 111] .

Rotavac® (Bharat Biotech International Limited) is a monovalent human-bovine RV vaccine. The vaccine consists of the 116E RV strain, which is a naturally occurring reassortant strain G9P [11] , containing 1 bovine RV gene P [11] and 10 human RV genes [112] . Rotavac® is the first to be introduced into a public vaccination program as of April 2016 when it was introduced in four states in India [113] . Rotasiil® is a live attenuated human-bovine reassortant pentavalent RV vaccine that contains genes encoding the VP7 of serotypes G1, G2, G3, G4, and G9. In March and September 2018 Rotavac® and Rotasiil®, respectively achieved WHO prequalification. Rotavac® has a vaccine efficacy of 53.6% for severe RV diarrhea in India [112] , while Rotasiil® has efficacies of 60.5 to 66.7% in India [114] and Niger respectively [115] . Rotasiil® can safely be delivered with decreased dependence on the availability of a cold chain [116] .

The Lanzhou Institute of Biological Products manufactures the Lanzhou Lamb RV vaccine (LLR). It is a monovalent lamb vaccine strain G10P [12] , attenuated by cell passage [117] , and was licensed in China in 2000. When given to children between 9 and 35 months old, one dose of the LLR vaccine conferred partial protection [118] . Vaccine effectiveness in children under 5 years of age was recently estimated at 35% (13 to 52%) against RV diarrhea and 53% (15 to 75%) against moderate-tosevere RV diarrhea based on a large case-controlled study [119] .

Rotavin-M1 vaccine is manufactured by the Center for Research and Production of Vaccines and Biologicals and was licensed for use in Vietnam in 2012. The vaccine was derived from an attenuated strain, G1P [8] , isolated from a Vietnamese child. A clinical trial found the vaccine to be safe and immunogenic in Vietnamese infants [120] .

Another candidate RV vaccine, RV3-BB, was developed from a neonatal strain G3P [6] identified in Australia, with ongoing early clinical studies conducted in New Zealand and now underway in Indonesia. It was also successfully implemented for vaccination of neonates [121] . Table 4 describes the comparison of all oral RV vaccines developed and used so far.

Intussusception, neutralizing antibodies present in breast milk, as well as the lower vaccine effectiveness in less developed settings has stimulated interest in an alternative, parenteral approach to immunization [123] [124] [125] [126] . The inactivated rotavirus particles, protein sub-units or virus-like particles (VLPs, structurally-similar to live virus) are being investigated as rotavirus vaccine candidates [125, 127, 128] .

Three types of animal models have been used to evaluate protective efficacy of VLPs: infection models (adult mice and rabbits), disease models (gnotobiotic piglets), and models evaluating passive protection (neonatal mice and calves) [129] . Gnotobiotic pig was used to assessed the immunogenicity and protection of a candidate inactivated rotavirus vaccine (IRV), the human strain CDC-9 (G1P[8] [130] and attenuated Wa human rotavirus [AttHRV] or non replicating Wa 2/6 rotavirus-like particles [131] . Mice, rabbits, and piglets were used to evaluate the efficacy of VPL such as 2/6-VLPs (consisting of VP2 and VP6) [129] and RF 8-2/6/7-VLPs [132] . Human clinical trial recently assessed in South African toddlers and infants was done for the subunit vaccine P2-VP8-P [8] [133, 134] .

RV vaccination does not completely protect young children against infection, but it reduce the severity of RVGE [135] . RV vaccines are highly effective in preventing severe gastroenteritis in young children during the first 5 years of their life, particularly in developed countries [136] . The SES of a country seems to influence RV vaccine effectiveness [137] . Vaccination was predicted to prevent 93, 86, and 51% of severe RVGE in high, middle, and low SES, respectively [126] . Analysis of the data for the Asia region found median vaccine effectiveness of 94% in low child mortality countries, 64% in medium child mortality countries, and 49% in high child mortality countries [138] . Factors that might contribute to this phenomenon including gut microbiota, genetic factors, transplacental antibodies, enteric pathogens, and environmental enteropathy [139, 140] . Evidence suggests that vaccine efficacy may vary by setting, due to regional differences in circulating RV vaccine strains and reduced efficacy of oral vaccines in settings with a high prevalence of malnutrition and gastrointestinal infections [141] . Pooled efficacy estimate of Rotarix® and RotaTeq® against severe RVGE in industrialized countries is 88% during the first year of age and 83% during the second year. However, RV vaccine efficacy is much lower in countries where the mortality rate for children under 5 years of age is high [142] . The efficacy of Rotarix® and RotaTeq® in the U.S. depends on the level of exposure during the RV season [143] . It can be concluded that vaccine efficacy is affected by individual factors such as nutritional level, gut microbiota, genetic factor, transplacental antibody and environmental enteropathy and external factors including SES, circulating vaccine strain, childhood mortality rate, and RV season in each country. Additionally, RV vaccination confers herd protection among infants and children under 5 years old who had not been vaccinated [144] [145] [146] . In developing countries with lower RV vaccine efficacy and coverage, indirect protection gain from herd immunity is more significant than in industrialized countries where vaccine efficacy and coverage exceed 90% [142] .

Many countries in Southeast Asia have not implemented national RV vaccination programs including Cambodia, Indonesia, Lao PDR, Malaysia, Myanmar, Singapore, Thailand and Vietnam. One reason is because of uncertainties regarding the cost-effectiveness of incorporating RV vaccination into the NIP. In addition, the vaccine's decreased efficacy in LIC settings has discouraged its introduction. Prevention of diarrhea in these countries has focused on patient treatment and the management of water quality, sanitation, and hygiene [84] .

In Indonesia, the RV vaccine has been commercially available since 2011. Indonesia's national vaccine manufacturer, PT. Bio Farma, Bandung, is developing an RV vaccine using G3P [6] strain in collaboration with the Murdoch Children's Research Institute in Melbourne, Australia [125] . Bio Farma is currently driving clinical development, intending to introduce the vaccine into the Indonesian NIP by 2021, and eventually develop a product for the global market [128] .

Currently Rotarix® and RotaTeq® are commercially available in Malaysia through private health providers [147] . However, RV vaccine is not included in Malaysia NIP because it is not considered permissible under Islamic shariah law (halal) [84] . The current oral rotavirus vaccines use porcine trypsin in the manufacturing process [148] . There are also concerns about competing public health priorities and price [84] . The Health Ministry recently said the RV vaccine would be included in NIP if the associated mortality rate for children aged 5 and below exceeded 10%. However, the childhood mortality rates in Malaysia was 0.5% in 2014 and 2.9% in 2015 [149] .

In Myanmar and Lao PDR where individual incomes are relatively low, international assistance will support for the RV vaccine introduction in 2020. The total amount of GAVI support for Myanmar is $4,088,000 [150] . Lao PDR is also planning RV vaccine introductions into the NIP in near future and assistance will be provided the Asian Development Bank and GAVI through an accelerated transition program [84] .

In July 2012, the Philippines became the first Asian country to introduce RV vaccines into its NIP. The Philippines has initially focus on immunizing children living in the poorest communities, which have the highest child morbidity and mortality rates from the diarrheal disease [151] . The target population was identified by the Department of Social Welfare and Development, but there were challenges with nationwide vaccine distribution. In 2014, vaccine introduction was limited to the Caraga region, where it was co-administered with oral polio vaccine and the pentavalent vaccine. By 2015, vaccine coverage was close to 90% in the province of Agusan del Sur within this region but subsequently decreased due to a supply shortage [84] . In Agusan del Sur, the RV vaccine became available to the poorest quintile in September 2012; in January 2013, availability was expanded to all age-eligible children in two municipalities, San Francisco and Prosperidad; it was available to the entire province in July 2014. RV vaccine introduction was associated with a substantial decline in diarrheal hospitalizations and outpatient consultations for diarrhea in Agusan del Sur, Philippines [152] .

Two live-attenuated, orally administrable RV vaccines Rotarix® and RotaTeq® were licensed in Singapore in October 2005 and July 2007, respectively [106] . To date, RV vaccination is optional in Singapore [65] .

The National Vaccine Committee of Thailand considered the introduction of an RV vaccine in 2010 in Sukhothai and Petchabun. Sukhothai province began a routine immunization program with an RV vaccine in October 2011. Evaluation of the first introduction was completed in 2017 and concluded that RV vaccine was highly effective in preventing diarrheal hospitalizations and conferring herd protection among older children who had not been vaccinated [144] . Therefore, universal RV vaccination for infants has been implemented in Thailand since January 2020.

Vietnam is located in a region of high RV infection incidence and eligible for financial support to introduce vaccines into the expanded program of immunization (EPI) from the GAVI [153] . In 2012, the local vaccine manufacturer Polyvac licensed Rotavin-M1, which is based on an attenuated G1P [8] strain. Rotavin-M1 will be offered to children less than 1 year through a two-dose schedule, vaccinating infants at 2 and 4 months [120] .

Rotarix® and RotaTeq® are also licensed in Vietnam and are available in the private sector, with approximately 590, 000 doses imported since 2017. That same year, the Government approved the introduction of RV vaccination into Vietnam's NIP by September 2019 with GAVI support. In 2021, the national government will pay for 80% of the vaccine cost, while GAVI will cover the remaining 20% and all operational costs. By 2022, all costs will be covered by the government [84] .

In LMICs, understanding the short-and long-term impact of intervention adoption on national budgets is critical for ensuring program sustainability [154] . Both budget impact and cost effectiveness are key criteria, among others, for policy makers deciding how to allocate limited resources [155] .. Vaccination would be considered a worthwhile investment for improving general childhood development and health levels in most LIC. The highest reduction in burden would be achieved in countries with a high disease burden (≥200 RV deaths per 100,000 children under 5 years old), but a similar reduction would be achieved in countries with a medium burden (100-200 RV deaths per 100,000 children under 5 years old) because disease burden reduction also depends heavily on population size and countryspecific vaccine efficacy adjusted for local RV serotype distributions [156] .

For GAVI non-eligible countries, the price for Rotarix® is $2.49-7.27, and for RotaTeq® is $3.65-5.09 [157] . For GAVI-eligible countries, the price per dose will depend on the country's gross national income per capita averaged over the previous 3 years. As such Indonesia, Malaysia, the Philippines, Singapore, and Thailand are fully not eligible for GAVI vaccine prices and will have to rely on self-financing [158] . For LIC in Asia, introducing vaccines would halve RV-related deaths and medical visits, leading to significant cost reductions [159] .

WHO-CHOICE (CHOosing Interventions that are Cost-Effective) uses the GDP as an indicator to develop the following widely referenced categories of cost-effectiveness. Disability-adjusted life years (DALYs) averted is a widely used indicator that allows easy comparison with a 'no vaccination' strategy and with others public health interventions. The ratio between costs per DALY averted and GDP per capita less than one is defined as highly cost effective. The ratio between 1 to < 3 and ≥ 3 are defined as cost effective and not cost effective, respectively [160] . The lowest and highest GDP values were in Myanmar with $1326 and Malaysia with $11,239, respectively [79] . Figure 4 shows the comparison between costs per DALY averted with each country's GDP in 2018. We excluded the Philippines because the RV vaccine already included in the country's NIP and Singapore because Singapore is a high-income country. According to categories of cost-effectiveness, RV vaccine introduction into Southeast Asia countries is highly cost-effective because the ratio between costs per DALY averted and GDP per capita it is less than one.

According to 2008-2018 RV surveillance data for Southeast Asia, 40.78% of all diarrheal cases were causes by RV. Acute diarrheal disease caused by RV is still a major cause of morbidity and mortality in children under 5 years old in Southeast Asia. Among all assessed Fig. 4 Comparison between cost per DALY averted and GDP per capita in Southeast Asia. Introducing the rotavirus vaccine in Southeast Asia is highly cost-effective because the ratio is less than one [79, 107, 137, 161] countries, the most predominant genotype distribution of RV changed from G1P [8] and G2P [4] into the rare and unusual genotypes G3P [8] , G8P [8] , and G9P [8] . Although the predominant RV strain has been changed, but the seasonality of RV infection remains unchanged. Continuous surveillance is necessary to determine whether they are regional genotype differences. Epidemiological data on RV prevalence will greatly facilitate vaccine development. In the mean time, the development of new vaccines will be needed if RVs are able to evade current vaccine immunity. More effective vaccines may also further decrease RV infection in children in LIC and LMIC, where currently available vaccines provide moderate efficacy. RV vaccine efficacy is affected by individual factors and external factors. Although most countries in Southeast Asia have not yet introduced national RV vaccination programs, such introduction is projected to be highly cost-effective because the ratio between costs per DALY averted and GDP per capita it is less than one. Authors' contributions FBL drafted the manuscript. FBL and YP wrote the article and prepared the figures. SV, NW, and YP revised and finished the final version of the manuscript. All authors read and approved the final manuscript.

Fajar Budi Lestari is a doctoral student at the Inter-Department of Biomedical Science, Faculty of Graduate School, at Chulalongkorn University, in Bangkok. Her primary research interests are zoonotic diseases and molecular epidemiology and evolution of rotavirus in humans and animals. Availability of data and materials Not applicable.

Ethics approval and consent to participate Not applicable.

Not applicable.

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Detection of a new virus by electron microscopy of faecal extracts from children with acute gastroenteritis

Letter: virus particles in gastroenteritis

Relation Between Viruses From Acute Gastroenteritis of Children and Newborn Calves

Fields Virology

Molecular interactions in rotavirus assembly and uncoating seen by highresolution cryo-EM

Rotavirus architecture at subnanometer resolution

Atomic model of an infectious rotavirus particle

Genetic and antigenic diversity of human rotaviruses: potential impact on vaccination programs

Full genome-based classification of rotaviruses reveals a common origin between human Wa-like and porcine rotavirus strains and human DS-1-like and bovine rotavirus strains

Uniformity of rotavirus strain nomenclature proposed by the rotavirus classification working group (RCWG)

Genotype constellation and evolution of group a rotaviruses infecting humans

VP6-sequence-based cutoff values as a criterion for rotavirus species demarcation

Candidate new rotavirus species in sheltered dogs

Candidate new rotavirus species in Schreiber's bats, Serbia

Unbiased whole-genome deep sequencing of human and porcine stool samples reveals circulation of multiple groups of rotaviruses and a putative zoonotic infection

Complete molecular genome analyses of equine rotavirus a strains from different continents reveal several novel genotypes and a largely conserved genotype constellation

Rabbit colony infected with a bovine-like G6P[11] rotavirus strain

Wholegenome characterization of a Peruvian alpaca rotavirus isolate expressing a novel VP4 genotype

ViPR: an open bioinformatics database and analysis resource for virology research

Evidence for presumable feline origin of sporadic G6P[9] rotaviruses in humans

Complete genomic sequence analyses of the first group a giraffe rotavirus reveals close evolutionary relationship with rotaviruses infecting other members of the Artiodactyla

Simian rotaviruses possess divergent gene constellations that originated from interspecies transmission and reassortment

Detection of substantial porcine group B rotavirus genetic diversity in the United States, resulting in a modified classification proposal for G genotypes

Evolution of rotavirus C in humans and several domestic animal species

Detection and characterization of group C rotaviruses in asymptomatic piglets in Ireland

Avian rotavirus enteritis -an updated review

Definition of two new groups of atypical rotaviruses

Genomic sequence of the first porcine rotavirus group H strain in the United States

Cameroonian fruit bats harbor divergent viruses, including rotavirus H, bastroviruses, and picobirnaviruses using an alternative genetic code

Rotavirus I in feces of a cat with diarrhea

Rotavirus vaccination and the global burden of rotavirus diarrhea among children younger than 5 years

WHOcoordinated global rotavirus surveillance network. 2008 estimate of worldwide rotavirus-associated mortality in children younger than 5 years before the introduction of universal rotavirus vaccination programmes: a systematic review and meta-analysis

Rotavirus and severe childhood diarrhea

Noroviruses: the Most common pediatric viral enteric pathogen at a Large University hospital after introduction of rotavirus vaccination

Norovirus and medically attended gastroenteritis in U.S. children

Major reduction of rotavirus, but not norovirus, gastroenteritis in children seen in hospital after the introduction of RotaTeq vaccine into the National Immunization Programme in Finland

World Health Organization-Coordinated Global Rotavirus Surveillance Network. Global, Regional, and National Estimates of Rotavirus Mortality in Children <5 Years of Age

Estimates of the global, regional, and national morbidity, mortality, and aetiologies of diarrhoea in 195 countries: a systematic analysis for the global burden of disease study

Rotavirus vaccine efficacy: current status and areas for improvement

Pediatric hospitalizations attributable to rotavirus gastroenteritis among Cambodian children: seven years of active surveillance

Detection of group a rotavirus strains circulating among children with acute diarrhea in Indonesia

Identification of rotavirus strains causing Diarrhoea in children under five years of age in Yogyakarta, Indonesia

Risk factors of rotavirus diarrhea in hospitalized children in Sanglah Hospital, Denpasar: a prospective cohort study

Association between Severe Dehydration in Rotavirus Diarrhea and Exclusive Breastfeeding among Infants at Dr. Hasan Sadikin General Hospital

Prevalence and clinical characteristics of rotavirus diarrhea in

Genotyping and clinical factors in pediatric diarrhea caused by rotaviruses: one-year surveillance in Surabaya

Identification of the P genotypes of rotavirus in children with acute diarrhea in Pekanbaru, Indonesia

Diarrhea among hospitalized children under five: a call for inclusion of rotavirus vaccine to the national immunization program in Indonesia

Equine-like G3 rotavirus strains as predominant strains among children in Indonesia in 2015-2016

Molecular characterisation of rotavirus strains detected during a clinical trial of the human neonatal rotavirus vaccine (RV3-BB) in Indonesia. Vaccine

Molecular Epidemiology and Clinical Features of Rotavirus Infection Among Pediatric Patients in East Java, Indonesia During 2015-2018: Dynamic Changes in Rotavirus Genotypes From Equine-Like G3 to Typical Human G1/G3

Rotavirus diarrhea in hospitalized children under 5 years of age in Vientiane

Rotavirus genotypes in Malaysia and universal rotavirus vaccination

Sentinel surveillance for rotavirus in children <5 years of age admitted for diarrheal illness to Yangon Children's hospital

First detection of DS-1-like G1P[8] human rotavirus strains from children with diarrhoea in the Philippines

Molecular characterization of rotavirus diarrhea among children aged under five years in the Philippines

Is your drinkingwater safe? A rotavirus outbreak linked to water refilling stations in the Philippines

A hospitalbased surveillance of rotavirus gastroenteritis in children <5 years of age in Singapore

Rotavirus vaccine RIX4414 efficacy sustained during the third year of life: a randomized clinical trial in an Asian population

Prevalence and phylogenetic analysis of rotavirus genotypes in Thailand between

Prevalence and genotypic Distribution of rotavirus in Thailand: a multicenter study

Prevalence of group a genotype human rotavirus among children with dirarrhea in Thailand

Increasing predominance of G8P[8] species a rotaviruses in children admitted to hospital with acute gastroenteritis in Thailand

The prevalence and genotype diversity of human rotavirus a circulating in Thailand

Complete genome analysis of a rare G12P[6] rotavirus isolated in Thailand in 2012 reveals a prototype strain of DS-1-like constellation

Genotype Distribution and Phylogenetic Analysis of Rotaviruses in Thailand and Emergence of Uncommon Genotypes

Predominant prevalence of human rotaviruses with the G1P[8] and G8P[8] genotypes with a short RNA profile in 2013 and 2014 in Sukhothai and Phetchaboon provinces

High prevalence of equine-like G3P[8] rotavirus in children and adults with acute gastroenteritis in Thailand

Emergence of G9P[8] rotaviruses in children with acute gastroenteritis in Thailand

Novel porcine-like human G26P[19] rotavirus identified in hospitalized paediatric diarrhoea patients in Ho Chi Minh City

Epidemiology of acute diarrhea caused by rotavirus in sentinel surveillance sites of Vietnam

GDP Per Capita

Rotaviruses: is their surveillance needed? Vaccine

Serotype diversity and reassortment between human and animal rotavirus strains: implications for rotavirus vaccine programs

Distribution of rotavirus strains and strain-specific effectiveness of the rotavirus vaccine after its introduction: a systematic review and metaanalysis

Reassortment of human rotavirus gene segments into G9P[8] rotavirus strain over a four year period: 2013-2016

Disease Prevention through Immunization in the Western Pacific Region

Molecular epidemiology of rotaviruses in the south-east Asian region from

Rotavirus gastroenteritis and weather

Rotavirus and other enteropathogens in childhood acute diarrhoea: a study of two centres in Malaysia

Rotavirus diarrhoea among children aged less than 5 years at Mahosot hospital, Vientiane, Lao PDR

Seasonality of rotavirus disease in the tropics: a systematic review and meta-analysis

The seasonality of diarrheal pathogens: a retrospective study of seven sites over three years

Seasonality of rotavirus in South Asia: a meta-analysis approach assessing associations with temperature, precipitation, and vegetation index

Survival and vehicular spread of human rotaviruses: possible relation to seasonality of outbreaks

Global burden of childhood pneumonia and diarrhoea

Rotavirus vaccines: an update

Rotavirus Immunization coverage

Global rotavirus vaccine introductions and coverage

Protection studies in colostrum-deprived piglets of a bovine rotavirus vaccine candidate using human rotavirus strains for challenge

Pérez-Schael I. Efficacy of a quadrivalent rhesus rotavirus-based human rotavirus vaccine aimed at preventing severe rotavirus diarrhea in infants and young children

Rotavirus vaccines: an overview

Rotavirus intussusception investigation team. Intussusception among infants given an oral rotavirus vaccine

Rotavirus vaccines: a story of success

Efficacy, immunogenicity and safety of a human rotavirus vaccine RIX4414 in Singaporean infants

Intussusception and Monovalent Rotavirus Vaccination in Singapore: Self-Controlled Case Series and Risk-Benefit Study

Safety and efficacy of an attenuated vaccine against severe rotavirus gastroenteritis

An update of paediatric intussusception incidence in Singapore: 1997-2007, 11 years of intussusception surveillance

Safety and efficacy of a pentavalent human-bovine (WC3) reassortant rotavirus vaccine

Update on intussusception following rotavirus vaccine administration: World Health Organization

Reevaluating the potential impact and cost-effectiveness of rotavirus vaccination in 73 Gavi countries: a modelling study

Improving rotavirus vaccine coverage: can newer-generation and locally produced vaccines help?

World Health Organization. Rotavirus Immunization Coverage

Efficacy of a monovalent human-bovine (116E) rotavirus vaccine in Indian infants: a randomised, double-blind, placebo-controlled trial

VIEW-hub report: global vaccine introduction and implementation

A randomized phase III clinical trial to assess the efficacy of a bovine-human reassortant pentavalent rotavirus vaccine in Indian infants

Efficacy of a low-cost, heat-stable Oral rotavirus vaccine in Niger

Stability of heat stable, live attenuated rotavirus vaccine (ROTASIIL®)

Selection and characterization of strain LLR-85 for oral rotavirus live vaccine

Rotavirus gastroenteritis infection among children vaccinated and unvaccinated with rotavirus vaccine in southern China: a population-based assessment

Effectiveness of the live attenuated rotavirus vaccine produced by a domestic manufacturer in China studied using a population-based case-control design

Rotavin-M1 Vaccine Trial Group. A dose-escalation safety and immunogenicity study of a new live attenuated human rotavirus vaccine (Rotavin-M1) in Vietnamese children

Human neonatal rotavirus vaccine (RV3-BB) to target rotavirus from birth

Current and Upcomming Rotavirus Vaccine

Decreased performance of live attenuated, oral rotavirus vaccines in low-income settings: causes and contributing factors

Correlates of protection against human rotavirus disease and the factors influencing protection in low-income settings

The rotavirus vaccine development pipeline

Understanding reduced rotavirus vaccine efficacy in low socio-economic settings

Next generation rotavirus vaccine. In: WHO Product Development for Vaccines Advisory Committee

Current and new rotavirus vaccines

Host, viral, and vaccine factors that determine protective efficacy induced by rotavirus and virus-like particles (VLPs)

Inactivated rotavirus vaccine induces protective immunity in gnotobiotic piglets

An oral versus intranasal prime/ boost regimen using attenuated human rotavirus or VP2 and VP6 virus-like particles with immunostimulating complexes influences protection and antibody-secreting cell responses to rotavirus in a neonatal gnotobiotic pig model

Parenteral administration of RF 8-2/ 6/7 rotavirus-like particles in a one-dose regimen induce protective immunity in mice

Safety and immunogenicity of a parenterally administered rotavirus VP8 subunit vaccine in healthy adults

Safety and immunogenicity of a parenteral P2-VP8-P[8] subunit rotavirus vaccine in toddlers and infants in South Africa: a randomised, double-blind, placebocontrolled trial

Cost-effectiveness of rotavirus vaccination in Vietnam

Cost-effectiveness of rotavirus immunization in Indonesia: taking breastfeeding patterns into account

Effectiveness of rotavirus vaccine in preventing severe gastroenteritis in young children according to socioeconomic status

Rotavirus vaccines: effectiveness, safety, and future directions

Differences of Rotavirus Vaccine Effectiveness by Country: Likely Causes and Contributing Factors

Causes of impaired oral vaccine efficacy in developing countries

The effect of rotavirus vaccine on diarrhoea mortality

Real-world impact of rotavirus vaccination

Reduced rotavirus vaccine effectiveness among children born during the rotavirus season: a pooled analysis of 5 case-control studies from the Americas

Evaluating the first introduction of rotavirus vaccine in Thailand: moving from evidence to policy

Infant rotavirus vaccination may provide indirect protection to older children and adults in the United States

Estimating the herd immunity effect of rotavirus vaccine

Household catastrophic healthcare expenditure and impoverishment due to rotavirus gastroenteritis requiring hospitalization in Malaysia

Religious and community leaders' acceptance of rotavirus vaccine introduction in Yogyakarta, Indonesia: a qualitative study

Rotavirus: Govt urged to protect kids with vaccine

Rotavirus Disease and Vaccines in Asia

Effectiveness of monovalent rotavirus vaccine in the Philippines

Health economics of rotavirus immunization in Vietnam: potentials for favorable costeffectiveness in developing countries

The decision making process on new vaccines introduction in South Africa

Capturing budget impact considerations within economic evaluations: a systematic review of economic evaluations of rotavirus vaccine in low-and middle-income countries and a proposed assessment framework

Health and economic impact of rotavirus vaccination in GAVI-eligible countries

Costs of vaccine programs across 94 low-and middle-income countries

Rotavirus: common, severe, devastating, preventable

Economic costs of rotavirus gastroenteritis and cost-effectiveness of vaccination in developing countries

Guidelines for estimating costs of introducing new vaccines into the national immunization system

Economic evaluation of human rotavirus vaccine in Thailand

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