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International Archives of Occupational and Environmental Health
Published in: International Archives of Occupational and Environmental Health 6/2021

01-08-2021 | Tuberculosis | Review Article

Occupational exposure and challenges in tackling M. bovis at human–animal interface: a narrative review

Authors: K. Renuga Devi, L. J. Lee, Lee Tze Yan, Amin-Nordin Syafinaz, I. Rosnah, V. K. Chin

Published in: International Archives of Occupational and Environmental Health | Issue 6/2021

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Abstract

Zoonotic tuberculosis caused by Mycobacterium bovis (M. bovis), a member of Mycobacterium tuberculosis complex (MTBC) has increasingly gathered attention as a public health risk, particularly in developing countries with higher disease prevalence. M. bovis is capable of infecting multiple hosts encompassing a number of domestic animals, in particular cattle as well as a broad range of wildlife reservoirs. Humans are the incidental hosts of M. bovis whereby its transmission to humans is primarily through the consumption of cattle products such as unpasteurized milk or raw meat products that have been contaminated with M. bovis or the transmission could be due to close contact with infected cattle. Also, the transmission could occur through aerosol inhalation of infective droplets or infected body fluids or tissues in the presence of wound from infected animals. The zoonotic risk of M. bovis in humans exemplified by miscellaneous studies across different countries suggested the risk of occupational exposure towards M. bovis infection, especially those animal handlers that have close and unreserved contact with cattle and wildlife populations These animal handlers comprising of livestock farmers, abattoir workers, veterinarians and their assistants, hunters, wildlife workers as well as other animal handlers are at different risk of contracting M. bovis infection, depending on the nature of their jobs and how close is their interaction with infected animals. It is crucial to identify the underlying transmission risk factors and probable transmission pathways involved in the zoonotic transmission of M. bovis from animals to humans for better designation and development of specific preventive measures and guidelines that could reduce the risk of transmission and to protect these different occupational-related/populations at risk. Effective control and disease management of zoonotic tuberculosis caused by M. bovis in humans are also hindered by various challenges and factors involved at animal–human interface. A closer look into factors affecting proper disease control and management of M. bovis are therefore warranted. Hence, in this narrative review, we have gathered a number of different studies to highlight the risk of occupational exposure to M. bovis infection and addressed the limitations and challenges underlying this context. This review also shed lights on various components and approaches in tackling M. bovis infection at animal–human interface.
Literature
Adesokan HK, Jenkins AO, Van Soolingen D, Cadmus SI (2012) Mycobacterium bovis infection in livestock workers in Ibadan, Nigeria: evidence of occupational exposure. Int J Tuberc Lung Dis 16:1388–1392CrossRef
Adesokan HK, Akinseye VO, Sulaimon MA (2018) Knowledge and practices about zoonotic tuberculosis prevention and associated determinants amongst livestock workers in Nigeria; 2015. PLoS ONE 13(6):e0198810CrossRef
Al-Thwani AN, Al-Mashhadani MS (2016) Tuberculosis in slaughtered cattle and workers in some abattoirs of Baghdad governorate. Int J Mycobacteriol 5:S250–S251CrossRef
Alvarez J, Perez AM, Bezos J, Casal C, Romero B, Rodriguez-Campos S, Saez-Llorente JL, Diaz R, Carpintero J, de Juan L, Domínguez L (2012) Eradication of bovine tuberculosis at a herd-level in Madrid, Spain: study of within-herd transmission dynamics over a 12 year period. BMC Vet Res 8:1–8CrossRef
Ameni G, Erkihun A (2007) Bovine tuberculosis on small-scale dairy farms in Adama town, central Ethiopia, and farmer awareness of the disease. Rev Sci Tech 26:711–720CrossRef
Ameni G, Regasa A (2001) Survey on bovine tuberculosis in cattle and its public health implications to cattle raising families in Wolaita Soddo, Southern Ethiopia. Ethiop J Anim Prod. 1:55–62
Ameni G, Tadesse K, Hailu E, Deresse Y, Medhin G, Aseffa A, Hewinson G, Vordermeier M, Berg S (2013) Transmission of Mycobacterium tuberculosis between farmers and cattle in central Ethiopia. PLoS ONE 8(10):e76891CrossRef
Anderson DP, Ramsey DS, Nugent G, Bosson M, Livingstone P, Martin PA, Sergeant E, Gormley AM, Warburton B (2013) A novel approach to assess the probability of disease eradication from a wild-animal reservoir host. Epidemiol Infect 141:1509–1521CrossRef
Annan A, Owusu M, Marfo KS, Larbi R, Sarpong FN, Adu-Sarkodie Y, Amankwa J, Fiafemetsi S, Drosten C, Owusu-Dabo E, Eckerle I (2015) High prevalence of common respiratory viruses and no evidence of Middle East respiratory syndrome coronavirus in Hajj pilgrims returning to Ghana, 2013. Trop Med Int Health 20:807–812CrossRef
Baker MG, Lopez LD, Cannon MC, De Lisle GW, Collins DM (2006) Continuing Mycobacterium bovis transmission from animals to humans in New Zealand. Epidemiol Infect 134:1068–1073CrossRef
Barlow ND (1991) A spatially aggregated disease/host model for bovine Tb in New Zealand possum populations. J Appl Ecol 28:777–793CrossRef
Barlow ND (2000) Non-linear transmission and simple models for bovine tuberculosis. J Anim Ecol 69:703–713CrossRef
Bengis RG, Schmitt SM, O’brien DJ (2002) Tuberculosis in free-ranging wildlife: detection, diagnosis and management. Rev Sci Tech 21:317–334CrossRef
Borja E, Borja LF, Prasad R, Tunabuna T, Toribio JA (2018) A retrospective study on bovine tuberculosis in cattle on Fiji: study findings and stakeholder responses. Front Vet Sci 5:270CrossRef
Bouchez-Zacria M, Courcoul A, Durand B (2018) The distribution of bovine tuberculosis in cattle farms is linked to cattle trade and badger-mediated contact networks in south-western France, 2007–2015. Front Vet Sci 5:173CrossRef
Brook RK, Wal EV, van Beest FM, McLachlan SM (2013) Evaluating use of cattle winter feeding areas by elk and white-tailed deer: implications for managing bovine tuberculosis transmission risk from the ground up. Prev Vet Med 108:137–147CrossRef
Brooks-Pollock E, Roberts GO, Keeling MJ (2014) A dynamic model of bovine tuberculosis spread and control in Great Britain. Nature 511:228–231CrossRef
Brunton LA, Prosser A, Pfeiffer DU, Downs SH (2018) Exploring the fate of cattle herds with inconclusive reactors to the tuberculin skin test. Front Vet Sci 5:228CrossRef
Buddle BM, Vordermeier HM, Chambers MA, de Klerk-Lorist LM (2018) Efficacy and safety of BCG vaccine for control of tuberculosis in domestic livestock and wildlife. Front Vet Sci 5:259CrossRef
Byrne AW, Allen AR, O’Brien DJ, Miller MA (2019) Bovine tuberculosis—international perspectives on epidemiology and management. Front Vet Sci 6:202CrossRef
Cantlay JC, Ingram DJ, Meredith AL (2017) A review of zoonotic infection risks associated with the wild meat trade in Malaysia. EcoHealth 14:361–388CrossRef
Carruth L, Roess AA, Mekonnen YT, Melaku SK, Nichter M, Salman M (2016) Zoonotic tuberculosis in Africa: challenges and ways forward. Lancet 388:2460–2461CrossRef
Chan HHY, Mpe J (2015) A rare cause of pulmonary tuberculosis. N Z Med J 128:81–83
Chauhan AS, George MS, Lindahl J, Grace D, Kakkar M (2019) Community, system and policy level drivers of bovine tuberculosis in smallholder periurban dairy farms in India: a qualitative enquiry. BMC Public Health 19:301CrossRef
Cleaveland S, Shaw DJ, Mfinanga SG, Shirima G, Kazwala RR, Eblate E, Sharp M (2007) Mycobacterium bovis in rural Tanzania: risk factors for infection in human and cattle populations. Tuberculosis (Edinb) 87:30–43CrossRef
Conlan AJ, McKinley TJ, Karolemeas K, Pollock EB, Goodchild AV, Mitchell AP, Birch CP, Clifton-Hadley RS, Wood JL (2012) Estimating the hidden burden of bovine tuberculosis in Great Britain. PLoS Comput Biol 8:e1002730CrossRef
Cordova E, Gonzalo X, Boschi A, Lossa M, Robles M, Poggi S, Ambroggi M (2012) Human Mycobacterium bovis infection in Buenos Aires: epidemiology, microbiology and clinical presentation. Int J Tuberc Lung Dis 16:415–417CrossRef
Cosgrove MK, O’Brien DJ, Ramsey DS (2018) Baiting and feeding revisited: modeling factors influencing transmission of tuberculosis among deer and to cattle. Front Vet Sci 5:306CrossRef
Cosivi O, Grange JM, Daborn CJ, Raviglione MC, Fujikura T, Cousins D, Robinson RA, Huchzermeyer HF, de Kantor I, Meslin FX (1998) Zoonotic tuberculosis due to Mycobacterium bovis in developing countries. Emerg Infect Dis 4:59CrossRef
Cousins DV (2001) Mycobacterium bovis infection and control in domestic livestock. Rev Sci Tech 20:71–85CrossRef
Cousins DV, Francis BR, Gow BL (1989) Advantages of a new agar medium in the primary isolation of Mycobacterium bovis. Vet Microbiol 20:89–95CrossRef
Cross M, Heeren A, Cornicelli LJ, Fulton DC (2018) Bovine tuberculosis management in northwest Minnesota and implications of the risk information seeking and processing (RISP) model for wildlife disease management. Front Vet Sci 5:190CrossRef
Dasse F, Dufour B, Duong M (2019) Guidelines for monitoring workers after occupational exposure to bovine tuberculosis. Med Mal Infect 49:563CrossRef
de Klerk LM, Michel AL, Bengis RG, Kriek NP, Godfroid J (2010) BCG vaccination failed to protect yearling African buffaloes (Syncerus caffer) against experimental intratonsilar challenge with Mycobacterium bovis. Vet Immunol Immunopathol 137:84–92CrossRef
de la Rua-Domenech R (2006) Human Mycobacterium bovis infection in the United Kingdom: incidence, risks, control measures and review of the zoonotic aspects of bovine tuberculosis. Tuberculosis 86:77–109CrossRef
Deffontaines G, Vayr F, Rigaud E, Brenot D, Boschiroli ML, Caron V, Comolet T, Coutin P, Dasse F, Dufour B, Duong M (2019) Guidelines for monitoring workers after occupational exposure to bovine tuberculosis. Medecine et maladies infectieuses. 49(8):563–73
Duguma A, Abera S, Zewdie W, Belina D, Haro G (2017) Status of bovine tuberculosis and its zoonotic implications in Borana zone southern Ethiopia. Trop Anim Health Prod 49:445–450CrossRef
Fekadu F, Beyene TJ, Beyi AF, Edao BM, Tufa TB, Woldemariyam FT, Gutema FD (2018) Risk perceptions and protective behaviors toward bovine tuberculosis among abattoir and butcher workers in Ethiopia. Front Vet Sci 5:169CrossRef
Fischer EA, Van Roermund HJ, Hemerik L, Van Asseldonk MA, De Jong MC (2005) Evaluation of surveillance strategies for bovine tuberculosis (Mycobacterium bovis) using an individual based epidemiological model. Prev Vet Med 67:283–301CrossRef
Garner MG, Hamilton SA (2011) Principles of epidemiological modelling. Rev Sci Tech 30:407CrossRef
Gormley E, Corner LA (2018) Wild animal tuberculosis: stakeholder value systems and management of disease. Front Vet Sci 5:327CrossRef
Graham J, Smith GC, Delahay RJ, Bailey T, McDonald RA, Hodgson D (2013) Multi-state modelling reveals sex-dependent transmission, progression and severity of tuberculosis in wild badgers. Epidemiol Infect 141:1429–1436CrossRef
Griffin JM, Williams DH, Kelly GE, Clegg TA, O’boyle I, Collins JD, More SJ (2005) The impact of badger removal on the control of tuberculosis in cattle herds in Ireland. Prev Vet Med 67:237–266CrossRef
Gumi B, Schelling E, Firdessa R, Aseffa A, Tschopp R, Yamuah L, Young D, Zinsstag J (2011) Prevalence of bovine tuberculosis in pastoral cattle herds in the Oromia region, southern Ethiopia. Trop Anim Health Prod 43:1081CrossRef
Gumi B, Schelling E, Berg S, Firdessa R, Erenso G, Mekonnen W, Hailu E, Melese E, Hussein J, Aseffa A, Zinsstag J (2012) Zoonotic transmission of tuberculosis between pastoralists and their livestock in south-east Ethiopia. EcoHealth 9:139–149CrossRef
Habitu T, Areda D, Muwonge A, Tessema GT, Skjerve E, Gebrehiwot T (2019) Prevalence and risk factors analysis of bovine tuberculosis in cattle raised in mixed crop-livestock farming system in Tigray region, Ethiopia. Transbound Emerg Dis 66:488–496CrossRef
Hadi SA, Waters WR, Palmer M, Lyashchenko KP, Sreevatsan S (2018) Development of a multidimensional proteomic approach to detect circulating immune complexes in cattle experimentally infected with Mycobacterium bovis. Front Vet Sci 5:141CrossRef
Hambolu D, Freeman J, Taddese HB (2013) Predictors of bovine TB risk behaviour amongst meat handlers in Nigeria: a cross-sectional study guided by the health belief model. PLoS ONE 8:e56091CrossRef
Hardstaff JL, Bulling MT, Marion G, Hutchings MR, White PC (2013) Modelling the impact of vaccination on tuberculosis in badgers. Epidemiol Infect 141:1417–1427CrossRef
Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, Zhang L, Fan G, Xu J, Gu X, Cheng Z (2020) Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet 395:497–506CrossRef
Islam SS, Rumi TB, Kabir SL, van der Zanden AG, Kapur V, Rahman AA, Ward MP, Bakker D, Ross AG, Rahim Z (2020) Bovine tuberculosis prevalence and risk factors in selected districts of Bangladesh. PLoS ONE 15:e0241717CrossRef
Jagielski T, Minias A, van Ingen J, Rastogi N, Brzostek A, Żaczek A, Dziadek J (2016) Methodological and clinical aspects of the molecular epidemiology of Mycobacterium tuberculosis and other mycobacteria. Clin Microbiol Rev 29:239–290CrossRef
Karesh WB, Cook RA, Gilbert M, Newcomb J (2007) Implications of wildlife trade on the movement of avian influenza and other infectious diseases. J Wildl Dis 43:S55
Kazoora HB, Majalija S, Kiwanuka N, Kaneene JB (2016) Knowledge, attitudes and practices regarding risk to human infection due to Mycobacterium bovis among cattle farming communities in western Uganda. Zoonoses Public Health 63:616–623CrossRef
Kemal J, Sibhat B, Abraham A, Terefe Y, Tulu KT, Welay K, Getahun N (2019) Bovine tuberculosis in eastern Ethiopia: prevalence, risk factors and its public health importance. BMC Infect Dis 19:39CrossRef
Khattak I, Mushtaq MH, Ahmad MUD, Khan MS, Haider J (2016) Zoonotic tuberculosis in occupationally exposed groups in Pakistan. Occup Med (Lond) 66:371–376CrossRef
Lassausaie J, Bret A, Bouapao X, Chanthavong V, Castonguay-Vanier J, Quet F, Mikota SK, Théorêt C, Buisson Y, Bouchard B (2015) Tuberculosis in Laos, who is at risk: the mahouts or their elephants? Epidemiol Infect 143:922–931CrossRef
Lavelle MJ, Kay SL, Pepin KM, Grear DA, Campa H III, VerCauteren KC (2016) Evaluating wildlife-cattle contact rates to improve the understanding of dynamics of bovine tuberculosis transmission in Michigan, USA. Prev Vet Med 135:28–36CrossRef
Livingstone PG, Hancox N, Nugent G, De Lisle GW (2015) Toward eradication: the effect of Mycobacterium bovis infection in wildlife on the evolution and future direction of bovine tuberculosis management in New Zealand. N Z Vet J 63:4–18CrossRef
Lombardi G, Botti I, Pacciarini ML, Boniotti MB, Roncarati G, Dal Monte P (2017) Five-year surveillance of human tuberculosis caused by Mycobacterium bovis in Bologna, Italy: an underestimated problem. Epidemiol Infect 145:3035–3039CrossRef
Lorente-Leal V, Liandris E, Castellanos E, Bezos J, Domínguez L, de Juan L, Romero B (2019) Validation of a real-time PCR for the detection of Mycobacterium tuberculosis complex members in bovine tissue samples. Front Vet Sci 2019:6
Luciano SA, Roess A (2020) Human zoonotic tuberculosis and livestock exposure in low-and middle-income countries: a systematic review identifying challenges in laboratory diagnosis. Zoonoses Public Health 67(2):97–111CrossRef
Marie-France H, Boschiroli ML, Saegerman C (2009) Classification of worldwide bovine tuberculosis risk factors in cattle: a stratified approach. Vet Res 40:50CrossRef
McGeary A (2008) The role of Mycobacterium bovis in tuberculosis in Africa. Med J Thera Africa 2:59–63
Meiring C, van Helden PD, Goosen WJ (2018) TB control in humans and animals in south Africa: a perspective on problems and successes. Front Vet Sci 5:298CrossRef
Mertoğlu A, Biçmen C, Karaarslan S, Buğdayci MH (2018) Pulmonary tuberculosis due to Mycobacterium bovis revealed by skin lesion in slaughterhouse worker. Clin Respir J 12:317–321CrossRef
Müller B, Dürr S, Alonso S, Hattendorf J, Laisse CJ, Parsons SD, Van Helden PD, Zinsstag J (2013) Zoonotic Mycobacterium bovis–induced tuberculosis in humans. Emerg Infect Dis 19:899CrossRef
Munyeme M, Muma JB, Munang’andu HM, Kankya C, Skjerve E, Tryland M (2010) Cattle owners’ awareness of bovine tuberculosis in high and low prevalence settings of the wildlife-livestock interface areas in Zambia. BMC Vet Res 6:21CrossRef
Naranjo V, Gortazar C, Vicente J, de la Fuente J (2008) Evidence of the role of European wild boar as a reservoir of Mycobacterium tuberculosis complex. Vet Microbiol 127:1–9CrossRef
Nishi JS, Shury T, Elkin BT (2006) Wildlife reservoirs for bovine tuberculosis (Mycobacterium bovis) in Canada: strategies for management and research. Vet Microbiol 112:325–338CrossRef
Nuru A, Mamo G, Zewude A, Mulat Y, Yitayew G, Admasu A, Medhin G, Pieper R, Ameni G (2017) Preliminary investigation of the transmission of tuberculosis between farmers and their cattle in smallholder farms in northwestern Ethiopia: a cross-sectional study. BMC Res Notes 10:31CrossRef
O’Brien DJ, Schmitt SM, Fitzgerald SD, Berry DE, Hickling GJ (2006) Managing the wildlife reservoir of Mycobacterium bovis: the Michigan, USA, experience. Vet Microbiol 112:313–323CrossRef
Olea-Popelka F, Muwonge A, Perera A, Dean AS, Mumford E, Erlacher-Vindel E, Forcella S, Silk BJ, Ditiu L, El Idrissi A, Raviglione M (2017) Zoonotic tuberculosis in human beings caused by Mycobacterium bovis—a call for action. Lancet Infect Dis 17:e21–e25CrossRef
Oloya J, Opuda-Asibo J, Kazwala R, Demelash AB, Skjerve E, Lund A, Johansen TB, Djonne B (2008) Mycobacteria causing human cervical lymphadenitis in pastoral communities in the Karamoja region of Uganda. Epidemiol Infect 136:636–643CrossRef
Palmer MV, Thacker TC (2018) Use of the human vaccine, Mycobacterium bovis bacillus Calmette Guérin in deer. Front Vet Sci 5:244CrossRef
Perez AM, Ward MP, Charmandarián A, Ritacco V (2002) Simulation model of within-herd transmission of bovine tuberculosis in Argentine dairy herds. Prev Vet Medicine 54:361–372CrossRef
Phepa PB, Chirove F, Govinder KS (2016) Modelling the role of multi-transmission routes in the epidemiology of bovine tuberculosis in cattle and buffalo populations. Math Biosci 277:47–58CrossRef
Radostits OM, Gay CC, Hinchcliff KW, Constable PD (2006) Diseases associated with Mycobacterium species. In: Veterinary medicine. A textbook of the diseases of cattle, horses, sheep, pigs and goats 10 ed, Edinburgh, London, New York, Oxford, Philadelphia, St Louis Sydney, Toronto. Elsevier, Amsterdam, pp 1008–1017
Rahman MM, Noor M, Islam KM, Uddin MB, Hossain FM, Zinnah MA, Mamun MA, Islam MR, Eo SK, Ashour HM (2015) Molecular diagnosis of bovine tuberculosis in bovine and human samples: implications for zoonosis. Future Microbiol 10:527–535CrossRef
Ramsey DS, O’Brien DJ, Smith RW, Cosgrove MK, Schmitt SM, Rudolph BA (2016) Management of on-farm risk to livestock from bovine tuberculosis in Michigan, USA, white-tailed deer: predictions from a spatially-explicit stochastic model. Prev Vet Med 134:26–38CrossRef
Raphaka K, Sánchez-Molano E, Tsairidou S, Anacleto O, Glass EJ, Woolliams JA, Doeschl-Wilson A, Banos G (2018) Impact of genetic selection for increased cattle resistance to bovine tuberculosis on disease transmission dynamics. Front Vet Sci 5:237CrossRef
Ribeiro-Lima J, Carstensen M, Cornicelli L, Forester JD, Wells SJ (2017) Patterns of cattle farm visitation by white-tailed deer in relation to risk of disease transmission in a previously infected area with bovine tuberculosis in Minnesota, USA. Transbound Emerg Dis 64:1519–1529CrossRef
Robinson PA (2019) Farmer and veterinarian attitudes towards the risk of zoonotic Mycobacterium bovis infection in northern Ireland. Vet Rec 185:2019CrossRef
Rodríguez E, Sánchez LP, Pérez S, Herrera L, Jiménez MS, Samper S, Iglesias M (2009) Human tuberculosis due to Mycobacterium bovis and M. caprae in Spain, 2004–2007. Int J Tuberc Lung Dis 13:1536–1541
S’aidu AS, Okolocha EC, Dzikwi AA, Gamawa AA, Ibrahim S, Kwaga JK, Usman A, Maigari SA (2015) Public health implications and risk factors assessment of Mycobacterium bovis infections among abattoir personnel in Bauchi state, Nigeria. J Vet Med 2015:718193
Santos N, Almeida V, Gortázar C, Correia-Neves M (2015) Patterns of Mycobacterium tuberculosis-complex excretion and characterization of super-shedders in naturally-infected wild boar and red deer. Vet Res 46:1–10CrossRef
Shrikrishna D, de la Rua-Domenech R, Smith NH, Colloff A, Coutts I (2009) Human and canine pulmonary Mycobacterium bovis infection in the same household: re-emergence of an old zoonotic threat? Thorax 64:89–91CrossRef
Sichewo PR, Michel AL, Musoke J, Etter E (2019) Risk factors for zoonotic tuberculosis at the wildlife–livestock–human Interface in south Africa. Pathogens 8:101CrossRef
Sichewo PR, Vander Kelen C, Thys S, Michel AL (2020) Risk practices for bovine tuberculosis transmission to cattle and livestock farming communities living at wildlife-livestock-human interface in northern KwaZulu Natal, south Africa. PLoS Negl Trop Dis 14:e0007618CrossRef
Sikka V, Chattu VK, Popli RK, Galwankar SC, Kelkar D, Sawicki SG, Stawicki SP, Papadimos TJ (2016) The emergence of Zika virus as a global health security threat: a review and a consensus statement of the INDUSEM Joint Working Group (JWG). J Glob Infect Dis 8:3CrossRef
Silva MR, Rocha AD, Araújo FR, Fonseca-Júnior AA, Alencar AP, Suffys PN, Costa RR, Moreira MA, Guimarães MD (2018) Risk factors for human Mycobacterium bovis infections in an urban area of Brazil. Mem Inst Oswaldo Cruz 2018:113
Smith GC, Delahay RJ (2018) Modeling as a decision support tool for bovine TB control programs in wildlife. Front Vet Sci 5:276CrossRef
Smith RL, Schukken YH, Lu Z, Mitchell RM, Grohn YT (2013a) Development of a model to simulate infection dynamics of Mycobacterium bovis in cattle herds in the United States. J Am Vet Med Assoc 243:411–423CrossRef
Smith RL, Tauer LW, Schukken YH, Lu Z, Grohn YT (2013b) Minimization of bovine tuberculosis control costs in US dairy herds. Prev Vet Med 112:266–275CrossRef
Sunder S, Lanotte P, Godreuil S, Martin C, Boschiroli ML, Besnier JM (2009) Human-to-human transmission of tuberculosis caused by Mycobacterium bovis in immunocompetent patients. J Clin Microbiol 47:1249–1251CrossRef
Tebug S, Njunga GR, Chagunda MG, Mapemba JP, Awah-Ndukum J, Wiedemann S (2014) Risk, knowledge and preventive measures of smallholder dairy farmers in northern Malawi with regard to zoonotic brucellosis and bovine tuberculosis. Onderstepoort J Vet Res 81:01–06CrossRef
Teppawar RN, Chaudhari SP, Moon SL, Shinde SV, Khan WA, Patil AR (2018) Zoonotic tuberculosis: a concern and strategies to combat. In: Basic biology and applications of actinobacteria. IntechOpen
Thoen CO, LoBue PA, de Kantor I (2010) Why has zoonotic tuberculosis not received much attention? Int J Tuberc Lung Dis 14:1073–1074
Tigre W, Alemayehu G, Abetu T, Deressa B (2011) Preliminary study on public health implication of bovine tuberculosis in Jimma Town, south western Ethiopia. Glob Vet 6:369–373
Torres-Gonzalez P, Soberanis-Ramos O, Martinez-Gamboa A, Chavez-Mazari B, Barrios-Herrera MT, Torres-Rojas M, Cruz-Hervert LP, Garcia-Garcia L, Singh M, Gonzalez-Aguirre A, de Leon-Garduño AP (2013) Prevalence of latent and active tuberculosis among dairy farm workers exposed to cattle infected by Mycobacterium bovis. PLoS Negl Trop Dis 7:2013CrossRef
Tsairidou S, Allen A, Banos G, Coffey M, Anacleto O, Byrne AW, Skuce RA, Glass EJ, Woolliams JA, Doeschl-Wilson AB (2018) Can we breed cattle for lower bovine TB infectivity? Front Vet Sci 5:310CrossRef
Tsegaye W, Aseffa A, Mache A, Mengistu Y, Stefan B, Ameni G (2010) Conventional and molecular epidemiology of bovine tuberculosis in dairy farms in Addis Ababa city, the capital of Ethiopia. J Appl Res Vet Med 8:143
Twomey DF, Higgins RJ, Worth DR, Okker M, Gover K, Nabb EJ, Speirs G (2010) Cutaneous TB caused by Mycobacterium bovis in a veterinary surgeon following exposure to a tuberculous alpaca (Vicugna pacos). Vet Rec 166:175–177CrossRef
Ullah A, Khattak US, Ayaz S, Qureshi MS (2018) An emerging zoonosis of bovine tuberculosis-a neglected zoonotic disease (NZD) in work-related occupational groups in Pakistan. J Microb Pathog 2:105
Vayr F, Martin-Blondel G, Savall F, Soulat JM, Deffontaines G, Herin F (2018) Occupational exposure to human Mycobacterium bovis infection: a systematic review. PLoS Negl Trop Dis 12:e0006208CrossRef
VerCauteren KC, Lavelle MJ, Campa H III (2018) Persistent spillback of bovine tuberculosis from white-tailed deer to cattle in Michigan, USA: status, strategies, and needs. Front Vet Sci 5:301CrossRef
Wedlock DN, Skinner MA, de Lisle GW, Buddle BM (2002) Control of Mycobacterium bovis infections and the risk to human populations. Microbes Infect 4:471–480CrossRef
White PC, Lewis AJ, Harris S (1997) Fertility control as a means of controlling bovine tuberculosis in badger (Meles meles) populations in south–west England: predictions from a spatial stochastic simulation model. Proc R Soc B 264:1737–1747CrossRef
Wilkins MJ, Bartlett PC, Frawley B, O’Brien DJ, Miller CE, Boulton ML (2003) Mycobacterium bovis (bovine TB) exposure as a recreational risk for hunters: results of a Michigan hunter survey, 2001. Int J Tuberc Lung Dis 7:1001–1019
Wilkins MJ, Meyerson J, Bartlett PC, Spieldenner SL, Berry DE, Mosher LB, Kaneene JB, Robinson-Dunn B, Stobierski MG, Boulton ML (2008) Human Mycobacterium bovis infection and bovine tuberculosis outbreak, Michigan, 1994–2007. Emerg Infect Dis 14:657CrossRef
Wilkins MJ, Bartlett PC, Judge LJ, Erskine RJ, Boulton ML, Kaneene JB (2009) Veterinarian injuries associated with bovine TB testing livestock in Michigan, 2001. Prev Vet Med 89:185–190CrossRef
Willeberg P, Paisley LG, Lind P (2011a) Epidemiological models to support animal disease surveillance activities. Rev Sci Tech 30:603–614CrossRef
Willeberg P, Paisley LG, Lind P (2011b) The world organisation for animal health and epidemiological modelling: background and objectives. Rev Sci Tech 30:391CrossRef
Metadata
Title
Occupational exposure and challenges in tackling M. bovis at human–animal interface: a narrative review
Authors
K. Renuga Devi
L. J. Lee
Lee Tze Yan
Amin-Nordin Syafinaz
I. Rosnah
V. K. Chin
Publication date
01-08-2021
Publisher
Springer Berlin Heidelberg
Published in
International Archives of Occupational and Environmental Health / Issue 6/2021
Print ISSN: 0340-0131
Electronic ISSN: 1432-1246
DOI
https://doi.org/10.1007/s00420-021-01677-z

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