Peter Hale1, Malika Bouhenia2, Jesse Bliss1, Brianne A. Couturier3, Anita S. Iyer1, ... Francisco J. Luquero6,7, Marc R. Couturier3, Andrew S. Azman6, Daniel T. ... participants, community leaders in the UN House PoC, staff at the WHO Juba.
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Enteropathogen Distribution and Prevalence in Internally Displaced Persons Receiving an Oral Cholera Vaccine in South Sudan Peter Hale1, Malika Bouhenia2, Jesse Bliss1, Brianne A. Couturier3, Anita S. Iyer1, John Rumunu4, Stephen MarAn5, 2 6 6,7 3 6 1 Abdinasir Abubakar , David Sack , Francisco J. Luquero , Marc R. Couturier , Andrew S. Azman , Daniel T. Leung 1University
of Utah, Salt Lake City, UT, United States, 2World Health Organization, Juba, South Sudan, 3ARUP Laboratories, Salt Lake City, UT, United States, 4Republic of South Sudan Ministry of Health, Juba, South Sudan, 5World Health Organization, Geneva, Switzerland, 6Johns Hopkins University, Baltimore, MD, United States, 7Epicentre, Paris, France
Background
Pathogen presence and immune response:
Results
• Gastrointestinal infections are among the top killers of young children worldwide, accounting for more than 750,000 deaths a year1 • Previous studies have demonstrated a high burden of enteropathogen carriage among young children, even those without diarrhea, in lowincome countries.2 • Enteropathogen carriage has been associated with poor oral vaccine responses.3 • Data lacking regarding Enteropathogen carriage among those in refugee or Internally Displaced Person (IDP) camps
Objectives 1) Describe the distribution of pathogens in stool of healthy oral cholera vaccine recipients in an internally displaced persons camp. 2) Determine the relationship between pathogen carriage and immune responses to vaccine.
Methodology
!
1#5!yrs! (n=8)! 1" 2" 0" 0" 0" 0" 0" 0" 1" 0" 1" 0" 0" 2" 0" 0" 0" 0" 0" 7" 4"(50%)" 2"(25%)" 1"(13%)"
6#17!yrs! (n=27)! 4" 1" 3" 2" 1" 0" 0" 0" 1" 0" 7" 0" 0" 2" 0" 1" 0" 0" 0" 22" 13"(48%)" 7"(26%)" 1"(4%)"
18+!yrs! (n=51)! 1" 8" 2" 6" 3" 0" 1" 2" 2" 0" 3" 0" 1" 6" 0" 0" 0" 1" 0" 36" 22"(43%)" 10"(20%)" 3"(6%)"
Salmonella(spp.( Shigella(spp.( C.(jejuni/coli( STEC((stx1)(( STEC((stx2)( C.(upsiliensis( other(Campy(spp.( Cryptosporidium(spp.( Giardia(spp.( E.(histolytica( D.(fragilis( Cyclospora(spp.( Norovirus"GI" Norovirus"GII" Astrovirus" Adenovirus" Rotavirus" Sapovirus" V.(cholerae( Total(pathogens( ≥1(pathogens( ≥2(pathogens( ≥3(pathogens( " Table 1. Pathogen frequency by age group
Total! (n=86)! 6! 13! 5! 8! 4! 0! 1! 2! 4! 0! 11! 0! 1! 10! 0! 1! 0! 1! 0! 65! 39!(45%)! 19!(22%)! 5!(6%)!
Adenovirus (n=1)
Norovirus G1 (n=1)
proportion co−infected
Crypto (n=2)
1.00 0.75
• Bacterial pathogens (STEC, Shigella, Salmonella) among the most commonly carried o Potential for outbreak in the overcrowded conditions of an IDP or refugee camp5
• Determine contribution of asymptomatic enteropathogen carriage on symptomatic disease and spread within IDP camps • Larger sample size to examine relationship between enteropathogen carriage and oral vaccine response
0.50
Campy (other) (n=1)
0.25 0.00 STX2 (n=4)
References 1. Liu L, et al. 2012. Global, regional, and national causes of child mortality: an updated systematic analysis for 2010 with time trends since 2000. Lancet 379:2151-2161. 2. Taniuchi M, et al. 2013. Etiology of Diarrhea in Bangladeshi Infants in the First Year of Life Analyzed Using Molecular Methods. J Infect Dis 208:1794-802. 3. Parker EPK, et al. 2014. Influence of enteric infections on response to oral poliovirus vaccine: A systematic review and meta-analysis. J Infect Dis 210:853-64. 4. Iyer AS, et al. Immune Responses to an Oral Cholera Vaccine in Internally Displaced Persons in South Sudan. Sci Rep. 6:35742. 5. Lederer I, et al. 2015. Shigellosis in refugees, Austria, July to November 2015. Euro Surveill. 20:30081
STX1 (n=8)
Campy jejuni/coli(n=5)
Shigella (n=12)
Acknowledgements
co−infection
Figure 1. Pathogen co-occurrence patterns
Adenovirus
Norovirus G2
Norovirus G1
D. fragilis
Giardia
Crypto
Campy (other)
STX2
STX1
Campy jejuni/coli
Salmonella (n=6)
Shigella
• Viruses: • Astrovirus • Norovirus GI and GII • Adenovirus • Rotavirus • Sapovirus
Giardia (n=4)
Salmonella
• Parasites: • Cryptosporidium spp. • Giardia spp. • Dientamoeba fragilis • Entamoeba histoly8ca • Cyclospora spp.
• Nearly half (45%) of OCV recipients in an IDP camp in South Sudan had asymptomatic carriage of a detectable enteropathogen, and many with >1 pathogen o Carriage rates similar among different age groups (young children, older children, and adults)
Future Directions
D. fragilis (n=11)
infection
• Raw stool samples shipped from Juba to Utah on dry ice, kept at -‐80C • Stool was diluted in PBS at 1:10 raAo and extracted on the Chemagen II (Perkin Elmer) using a 2x Blood Lysis kit • Real-‐Ame PCR was performed on all stool for the following targets: • Bacteria: • Salmonella spp. • Shigella spp. • Campylobacter jejuni/coli/upsaliensis • STEC (Stx1, Stx2) • Campylobacter lari/urely8cus/hyointes8nalis • Vibrio cholerae
Discussion/Conclusion
• Underpowered to determine impact of pathogen carriage on immunogenicity
Norovirus G2 (n=10)
Microbiological analysis
Table 2. No significant associations (by Fisher Exact test) between seroconversion and pathogens
Figure 2. Higher number of pathogens is associated with higher baseline vibriocidal titers for Inaba (p = 0.01) but not Ogawa. Note: Inaba was the circulating strain in year prior to sampling
• Baseline vibriocidal titer associated with higher pathogen carriage o Enteropathogen carriage and exposures may be a marker for cholera risk
Sample Collection: • IDP camp in Juba, South Sudan • Stool collected from individuals enrolled in an oral cholera vaccine immunogenicity study in 20154 • No obvious or self-‐reported signs of acute diarrheal illness • Paired stool and serum samples collected pre-‐vaccinaAon, and serum samples at days 21 and 35 post-‐vaccinaAon
- Baseline Inaba titer though not Ogawa associated with presence of enteric pathogens (Figure 2) - Of 46 of subjects with two paired serum samples and baseline titer ≤80, 32 (70%) seroconverted (4-fold rise in vibricoidal titer)
The authors would like to thank the study staff, participants, community leaders in the UN House PoC, staff at the WHO Juba Country Office, IMC Staff (Dr Meroni Abraham, Alejandro Guzman, Kourtney Rusow, Emebet Dlasso). This work was sponsored by The National Institute of Health (K08 AI100923 grants to D.T.L, R01 AI106878 to E.T.R.), The Bill and Melinda Gates Foundation (OPP1089243 to A.S.A, Delivering Oral Vaccine Effectively (DOVE) Project, OPP153556 to D.A.S., F.J.L., A.S.A., and OPP 1089248 to WHO) and Margaret A Cargill Foundation grants to the WHO.
