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[进展] 新出现、再现以及被忽略的人兽共患病

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新出现、再现以及被忽略的人兽共患病
美国新发传染病杂志
Volume 16, Number 1–January 2010
据统计,目前感染人的病原体中60%属于人兽共患病。这些病原体中71%以上源于野生动物。通过获得新的能改变病原致病潜能的基因组合,或由于宿主在行为、社会经济学、环境的或生态学特征等方面的改变,这些病原体能变换宿主。本文主要对工业社会中影响人兽共患病的出现和再现动力学的因素进行讨论,并重点选择分析了一些案例,以便全面的了解人兽共患病的范围和多样性。

1新出现、再现以及被忽略的人兽共患病

新现和再现的病原体必须从多个层次进行考虑。首先,鉴定出以前未知的病原体。例如英国改变牛的喂养方式致使宿主范围扩大和牛海绵状脑病。同理,许多物种共处于一个压力环境下,会变异出现新的病原体,SARS-CoV就是见证。

由于构建堤坝或暴雨导致河流改变和水灾,1987、1997–1998和 2006–2007年间非洲暴发了裂谷热。许多人兽共患病病原体属于非专性病原体,其宿主呈现广泛的多样性。例如Q热的病原体贝氏柯克斯体,其感染宿主范围从家畜到野生动物、爬行动物、鱼类、鸟类和蜱。其他的病原体因为受宿主范围的限制,有特定的传播动力学。这些病原体包括猿免疫缺陷病毒1和2、裂谷病毒。许多人兽共患病病原体具有感染偶然宿主(例如人)的能力,此时通常为终末宿主感染。这些病原体包括无形体、埃立克体、立克次体、巴尔通体、西尼罗病毒和狂犬病毒。

有些人兽共患病在特殊条件下可表现非同寻常,其人传人的能力远远超出自然界中动物之间的循环,如最近在刚果钻石矿工中的一次鼠疫暴发,此次暴发始于1例矿工感染者,后来转成肺炎并导致136例继发性肺鼠疫和57例死亡。鼠疫的传播是复杂的和动态的,随机的和适应性的传播机制互相结合。发生较多的是快速传播,但也伴随着较慢的在地方性动物储存宿主之间的局部传播,这些储存宿主常通过媒介再传播到密度较低的宿主。其他人兽共患病在适宜的环境下,能导致人间传播,如埃博拉热、甲流、鼠疫、土拉杆菌和SARS。

新的和已出现的毒力特点可能进化且导致大规模传播并伴随致病性的变异,包括增加侵染性、扩大传播范围、毒素产生或对抗生素的耐药性。有迹象表明鼠疫在马达加斯加地区死灰复燃,其分离株对抗生素的耐药性显著增强。

突变是遗传变异的最终来源,自然选择、遗传飘移、基因组流动、基因重组等共同作用形成种群的基因结构。这种因素在病毒尤为引人关注,病毒基因小,世代交替时间短,在基因组复制中容易出错的RNA病毒尤为明显。然而,大多数突变是有害的,且处于宿主天然的和适应性的免疫压力下。突变率的上限受如下因素所决定:自然选择、基因组结构和避免失去生存力或遗传信息的能力。

根据进化理论,环境的变化如宿主免疫防御功能改变,有利于产生较高的突变率。然而,在实验的环境下,突变率的增加往往与病毒滴度较低有关。

进化演变并不总是病毒出现新宿主的先决条件。有些病毒宿主范围广泛 (例如痘病毒),但突变率却很低。而其他病毒像委内瑞拉马脑炎病毒,进化演变对产生有效感染或传播到新的宿主是必需的。因为病毒在传播到新的宿主时大多很难复制,大的变异更易于帮助病毒适应新的宿主。

2 与人兽共患病相关的因素

2.1休闲娱乐活动体育活动可使人们暴露于人兽共患病,猎杀野生动物与感染布鲁氏菌病、兔热病相关。感染钩端螺旋体的动物通过尿液排泄的活菌,可在水环境中生存相当一段时间。1998年的3项全能比赛结束后,474名运动员中有52名被诊断为钩端螺旋体病。

为延长冬季赛季,欧洲国家将赛马运往气候温暖的地区(如阿拉伯联合酋长国)。狩猎活动促进了动物大规模出口,如从波兰出口野兔(野兔是兔热病和布鲁氏菌病的可能贮主)。英国等其他国家繁殖了大量的野鸡用于秋季射猎时放飞,为蜱类提供了大量的宿主,增加了蜱类数量。2007年英国从法国进口野鸡也输入了一种较温和的人兽共患病(新城疫)。

2.2伴侣动物伴侣动物与人有多种接触,有机会传播各种人兽共患病。弓形虫生活周期中的有性阶段是在猫体内,人可因未采取卫生措施而暴露、感染。猫还是猫抓热的病原体巴尔通体的储存宿主。牛痘病毒也能通过与猫接触传染人。动物咬伤可致人兽共患病,多杀巴斯德菌感染就很典型。即使未被动物咬伤(如舔到伤口),也能导致感染。

狗是人类感染狂犬病毒的最可能来源,也可能是弓形虫的来源。随着被解救狗的输入及狗随主人国际旅行,在没有沙蝇作为媒介的情况下也出现利什曼病例,这种威胁愈加明显。狗能成为耐甲氧西林金葡菌的传染源,在抗菌素耐药性遗传元件的人兽共患传播中起重要作用。最近发生在地中海旅游者的地中海斑点热,其最可能的感染来源就是与当地狗接触。

猫和狗能将鼠疫或狂犬病带到人类的生活环境、且与人感染Q热和癣有关。动物食腐的习性使其接触到许多人兽共患病病原体,与人类同吃同住的密切生活关系,为许多疾病提供了传播机会。

宠物鼠近来被指控是其主人黄疸出血型钩端螺旋体病的感染来源。近年来市场上外来宠物大量增加,造成一些与爬行动物宠物相关的输入性沙门氏菌的传播。2003年美国暴发70人以上感染猴痘事件引起媒体关注。宠物贸易中将感染的非洲啮齿动物进口后,感染北美的本土土拨鼠,然后又将疾病传染人类。

2.3食用野味    狩猎和食用野生动物引起的人兽共患病不断引起全球关注。许多人认为野生动物肉是美味,因而使其发展成商品化的产业。追踪、捕捉、处理、野外屠宰和运送野味构成了交叉物种感染的风险。风险最高的为猎杀非人灵长类动物。对于血液传播的病原体,屠宰动物比运输、销售和食用野味的感染风险更大。

众多RNA病毒的高突变率及其在野生动物中暴露的增加,已经使它们在新现的人传人的人兽共患病中有显著优势;来自野味的RNA病毒可能在未来的新现传染病中占有一席之地。

2.4全球化和牲畜运输如今,人员、牲畜、食品或货物的大规模运输很常见,这为病原体的迅速扩散提供更多的机会。马肉中的旋毛虫跨越太平洋运输,感染了地球另一端的消费者。世界动物卫生组织、粮农组织严格控制动物运送。动物运输致使不同物种混合在拥挤不堪的环境中,抑制了抗感染免疫应答的产生,增加病原体逃逸。在这种情况下,易感物种迅速被感染。

2.5旅游事业    近年来旅游事业呈指数发展,这也增加了输入性人兽共患病。如各种斑点热、布氏菌病、类鼻疽、I型戊肝、蜱传脑炎和血吸虫病。迅速增加的非洲蜱咬热病例与去南撒哈拉和东加勒比的旅游者有关。据统计,每天有至少100万人进行国际旅行,每年达7亿。有必要详细地记录患者旅游史和患病情况。

2.6土地用途变化和城市化为了加强农业生产和获得更多的生活空间,人们在全球范围的森林滥伐和自然栖息地开发造成生态破坏、储存宿主数量改变和传播动力学的变化。宿主的不足可能迫使媒介寻找其他宿主,增加了疾病传播机会,莱姆病、埃立克体病、斑点热和无形体病人间病例的增加证实了这种情况。马来西亚开发森林建立橡胶种植园使得血吸虫病增加。

土地用途改变的结果,可能使野生生物改变觅食方式,从而接近人类和家畜。有证据显示,正是这种觅食方式的改变,与1999年马来西亚暴发的人、猪尼帕病毒感染相关。尼帕病毒一直是印度、孟加拉国内农村的严重问题。那里生活在人类居所附近的染疫蝙蝠向海枣树排尿,而人们常生食这种海枣。

人口的增长可以从人口统计中表现出来,由20世纪初的10亿到世纪末的60亿,预测到2050年将达到100亿。城市化人口的增加也很惊人,由1980年的39%增加到1997年的46%,预测2030年将增加到60%。高密度的人口聚集为疾病大规模暴发提供了条件。

3结论和前景

许多人兽共患病是机会性感染。食品可作为一种中介,将病原体从动物传播到人。在农场与动物接触、猎杀或被动物咬伤能增加疾病传播(如狂犬病和兔热病)。节肢动物媒介能大规模地将疾病传播到其他宿主,如西尼罗热和鼠疫。

改变农耕模式、生活方式和运输影响病原体生态的动力学。许多内在和外来的因素能使病原体产生变化,如突变、重组、选择和人为操作都能使病原体获得新的特性,可能产生新的流行病。

通过变换机会宿主而再现的疾病可能继续成为人类传染病的主要来源。改进公共卫生策略的重点放在对很可能发生再现传染病的地区加强监测。这些策略包括:加强储存宿主中病原体检测、暴发初期的及时检测、进行广泛的基础研究以确定有利于疾病再现的因素和有效控制措施(例如隔离和改善卫生条件)。

我们须从流行病学角度了解人兽共患病。需要鉴定病原体及其脊椎动物宿主和传播方式。需要鉴定疾病的时空模式(spatiotemporal disease patterns)及其随时间而产生的变化。这些特征可用于确定病原传播的动力学过程,从而解释观察到的疾病模式,最终可实现对新的区域疾病传播与流行的预测。

有了对预期疾病模式的知识储备,我们就能对付突如其来的变化。然而这些分析可能还不适合应对新出现的人兽共患病。可考虑用症候群的方法来加强检测,而不仅是搜索特定病原体。

对人间疾病的监测必须与加强纵向兽医学监测相结合,即加强对用于食品生产的动物及野生动物的监测。快速检测和加强控制措施(例如疫苗接种)是防止疾病传播的关键。新的分子方法(例如DNA芯片)为快速检测提供了前所未有的机会,但这些检测方法在用于常规实验室之前需要优化和确认。然而,对于鉴定特异病原体,仍需要更多的研究,以便对新现或再现的疾病进行及时处置。

明确病原体在媒介中如何复制,可能对人兽共患病的控制提供很大帮助。通过对储存宿主的人兽共患病的控制,对人类已经有了明显的保护功效。开发和使用抗病毒药物为其他预防途径,但是这些药物用于疾病大面积暴发时可能过于昂贵,耐药性的产生可导致随之而来对这些病原体治疗方法的失败。

我们不知道哪一种人兽共患病将会成为下一个严重的公共卫生威胁。然而,只要我们坚持不懈,努力提高应对病原体的能力,将来一定能有效地应对新现、再现以及被忽略的人兽共患病。

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 楼主| 发表于 2010-6-20 20:46 | 显示全部楼层
本帖最后由 潮水 于 2010-6-20 20:49 编辑

EMERGING INFECTIOUS DISEASEVolume 16, Number 1–January 2010SynopsisPublic Health Threat of New, Reemerging, and Neglected Zoonoses in the Industrialized World
The World Health Organization/Food and Agriculture Organization/World Organisation for Animal Health joint consultation on emerging zoonotic diseases, held in Geneva in 2004, defined an emerging zoonosis as "a pathogen that is newly recognized or newly evolved, or that has occurred previously but shows an increase in incidence or expansion in geographical, host or vector range" (www.who.int/zoonoses/emerging_zoonoses/en). Through continued alterations in human and animal demographics and environmental changes, new and recurring diseases are likely to continue to emerge.

The effects of zoonoses on human health and economics have recently been underscored by notable outbreaks such as those involving Nipah virus and severe acute respiratory syndrome (SARS) coronavirus (CoV). A recent retrospective study of 335 emerging infectious episodes over a 64-year period (1940–2004) emphasized the role of wildlife as a source of emerging infections. However, research efforts have typically been focused toward either humans or economically related species (1).

The frequency of these events increased substantially over the period of investigation (2). Such infections are now often perceived as agents of biologic warfare rather than infections with a long but insidious history in their appropriate ecologic niche. Why then are these infections becoming a serious public health concern? The answer is a complex multifactorial set of changing circumstances. To support the growing human population, we have an increasing demand for nutritional support, resulting in intensive agricultural practices, sometimes involving enormous numbers of animals, or multiple species farmed within the same region. These practices can facilitate infection to cross species barriers.

Additionally, we are witnessing increasing globalization, with persons (3), animals, and their products (4) moving around the world. This movement enables unprecedented spread of infections at speeds that challenge the most stringent control mechanisms. Furthermore, continual encroachment of humans into natural habitats by population expansion or tourism brings humans into new ecologic environments and provides opportunity for novel zoonotic exposure. Climatic changes have facilitated the expansion of compatible conditions for some disease vectors, remodeling dynamics for potentially new, emerging, and reemerging zoonoses (5). In the next 2 decades, climate change will be the most serious issue that dominates reemergence of pathogens into new regions.

Climate change also effects evolution of pathogens, and where relevant, their vectors. Continual mutation and recombination events give rise to variants with altered levels of fitness to persist and spread. Changing ecologic circumstances and pathogen diversity can give rise to variants with altered pathogenic potential. However, the host must not be ignored. Increased longevity and therapies for persons with diseases can modulate host susceptibility and concomitant infections and upset the evolving and dynamic infection balance.

Emerging, Reemerging, and Neglected Zoonoses
Data for this review were identified in PubMed searches and relevant journal articles and excluded those studies not published in English. Emerging or reemerging pathogens must be considered on multiple levels. First, pathogens not previously known have been identified. For example, alteration in the processing of cattle feed in the United Kingdom resulted in extended host range and emergence of bovine spongiform encephalopathy in cattle (6). Similarly, mixing of multiple species under stressful conditions can promote a species jump such as that witnessed with SARS-CoV (7). New opportunities can be created by climatic changes such as global warming and ecologic alterations facilitated through changed land use and movements of infected hosts, susceptible animals, or disease vectors.

In 1987, 1997–1998, and 2006–2007, outbreaks of infection with Rift Valley fever virus in Africa were associated with changes in river flow and flooding resulting from damming of rivers or heavy rainfall. Many zoonotic pathogens fall into the category of generalist agents exhibiting extensive host diversity, e.g., Coxiella burnetii, the etiologic agent of Q fever. This bacterium can successfully infect hosts ranging from domestic animals to wildlife, reptiles, fish, birds, and ticks.

Others agents have restricted specific transmission dynamics because of limited host ranges. These agents include simian immunodeficiency viruses 1 and 2, which are found in chimpanzees and sooty mangabees, and Rift Valley virus, which is transmitted by Aedes spp. and Culex spp. mosquitoes and found in sheep and goats. For many zoonotic agents, the potential to cause infection in accidental hosts, such as humans, exists, but often this represents a dead-end host. Pathogens such as Anaplasma spp., Erhlichia spp., Rickettsia spp., Bartonella spp., West Nile virus, and rabies virus can be included in this group.

From an epidemiologic point of view, "A reservoir should be defined as one or more epidemiologically connected populations or environments in which a pathogen can be permanently maintained and from which infection is transmitted to the defined target species" (8). Conversely, some zoonoses in specific conditions show remarkable ability for human-to-human transmission beyond the confines of natural sylvatic cycles. This ability was seen during a recent outbreak of plague among diamond miners in the Congo. This outbreak was initiated by an infection of a miner, which became pneumonic and resulted in 136 secondary cases of pneumonic plague and 57 deaths (9). Transmission of plague is complex and dynamic, with combinations of stochastic and adaptive mechanisms. As seen in this example, rapid transmission often occurs, but this is accompanied by slower, localized transmission among enzootic reservoir species, which often use vector-borne expansion among low-density hosts (10). Other zoonoses, given correct circumstances, can result in human-to-human transmission. These zoonoses include those that cause Ebola fever, influenza A, plague, tularemia, and SARS (11).

New or emerging virulence traits can evolve and result in large-scale transmission and concomitant alteration of pathogenicity. This new pathogenicity may include increased invasiveness, enhanced spread, toxin production, or antimicrobial drug resistance. Y. pestis has shown a resurgence in regions such as Madagascar, with isolates showing a marked increase in resistance to antimicrobial agents (12). Similarly, a recently evolved outer surface protein A serotype of a Lyme borreliosis spirochete (Borrelia garinii serotype 4), has shown particularly aggressive tendencies and is often associated with hyperinvasive infection (13). Concern has also been noted about increasingly frequent isolation of Corynebacterium ulcerans carrying the diphtheria toxigenic phage.

Mutation is the ultimate source of genetic variation, on which natural selection, genetic drift, gene flow, and recombination act to shape the genetic structure of populations. This factor is especially notable in viruses, which have relatively small genomes and short generation times, particularly among viruses with more error-prone RNA genomic replication (14). However, most mutations are deleterious and under pressure of innate and adaptive host immunity, viruses probably always experience selection for mutation rates >0. The upper limit on mutation rates will be determined by factors such as natural selection, genomic architecture, and the ability to avoid loss of viability or genetic information, albeit, that a loss of genetic information and increased specialization is observed in co-evolution with a host (15).

According to evolutionary theory, higher mutation rates should be favored in a changing environment, such as altered host immune defenses. However, in experimental settings, artificially increased mutation rates are often associated with lower virus titers. In addition, a complex relationship exists between underlying mutational dynamics and the ability to generate antigenic variation, which in turn has serious implications for the epidemiologic potential of the virus.

Evolutionary changes are not always a prerequisite for viral emergence in a new host. Some viruses (e.g., poxviruses), have a wide host range and show a relatively low mutation rate. However, in other viruses such as Venezuelan equine encephalitis virus, evolutionary change is essential for efficient infection and transmission to new hosts (16). Because most viruses replicate poorly when transferred to new hosts, greater variation is more likely to assist viral adaptation to its new host.

All too frequently, the diagnosis of zoonotic disease is delayed through lack of clinical suspicion or failure to obtain adequate clinical histories. Some zoonotic infections are unusual (e.g., scabies infection after handling of pet guinea pigs). Other infections may have a less obvious animal link. Mowing lawns is believed to be a risk factor for acquiring tularemia (caused by Francisella tularensis) in disease-endemic areas where lagomorph reservoirs may be killed by mowers or hedge trimmers (17).

For some infections, zoonotic transmission occurs indirectly through food. Human brucellosis is not usually acquired through animal contact but is transmitted more often by consumption of infected animal products such as unpasteurized dairy products (18). Salmonella spp. have repeatedly caused outbreaks of salmonellosis after persons have eaten uncooked eggs (19). Hepatitis E virus has been transmitted through consumption of uncooked deer meat (20).

Exposure routes may be airborne, as demonstrated for several outbreaks of Q fever (21). An ongoing airborne Q fever outbreak in the Netherlands related to goat farming has raised awareness of this previously neglected zoonosis (22). How humans were exposed to these animals would not have been apparent; the exposures were identified by epidemiologic mapping of the distribution of cases. These examples underscore the necessity of gathering comprehensive patient data to effectively diagnose zoonoses.

Recreational Zoonoses
Sporting activities can expose humans to zoonotic infections. Hunting wildlife has been associated with infections such as brucellosis and tularemia (23). Less obvious routes arise from activities such as water sports. Leptospira spp.–infected animals excrete viable organisms in their urine, which can persist in aquatic environments for prolonged periods. After a triathlon event in 1998, a total of 52 of 474 athletes tested were diagnosed with leptospirosis (24). Suspicion of water sport–related infections with hepatitis A and Leptospira spp. led to closure of an area of Bristol, United Kindom, where docks were used for recreational water activities (25).

Horses are now moved from countries in Europe to warmer regions (e.g., United Arab Emirates) to prolong the racing season during the winter. Hunting activities have promoted large-scale export of animals such as hares (possible reservoirs of tularemia and brucellosis) from Poland and the movement of potentially rabies-infected raccoons in the United States. In other countries such as the United Kingdom, pheasants are bred and released for shooting in the fall and provide plentiful hosts for questing ticks and increasing their abundance. Importation of pheasants into the United Kingdom from France was associated with introduction of a mild zoonotic infection (Newcastle virus disease) in 2007 (26).

Role of Companion Animals
Companion animals have many forms of contact and opportunities to transmit multiple zoonoses. The sexual stage of the life cycle of Toxplasma spp. occurs in cats, thus exposing humans to infection in situations in which hygienic measures have not been observed. Cats also serve as reservoir for Bartonella henselae, the etiologic agent of cat-scratch fever (27). Cowpox virus can also be transmitted to humans by contact with cats (28). Animal bites can result in zoonotic infections, typified by infection with Pasteurella multocida. Even in the absence of a bite, contact with animals (e.g., licking of wounds) can result in infection. More recently, attention has focused on transmission of Rickettsia felis into the human environment by cat fleas (29).

Dogs are the most likely source when humans become infected with rabies virus and are potential sources of Toxocara spp. This emerging threat is becoming apparent with importation of rescued dogs and global movement of dogs with their owners, which has resulted in several cases of leishmaniasis in the absence of sand fly vectors. Dogs can be a source of methicillin-resistant Staphylococcus aureus and could play a role in zoonotic spread of genetic elements responsible for antimicrobial drug resistance (30). Contact with dogs in Mediterranean regions has been implicated as a likely source of infection in recent cases of Mediterranean spotted fever reported in traveling humans (31).

Cats and dogs can introduce plague or rabies into human environments and have been associated with Q fever in humans and dermatophytosis (ringworm). Scavenger habits of these animals bring them into contact with many zoonotic agents, and close living relationships with humans such as sharing meal plates or beds offer many opportunities for disease transmission.

Pet rats have recently been incriminated as the source of Leptospira icterrohemoragiae infection in their owners. Psittacine birds are an established risk factor for acquisition of Chlamydophila psittaci. During recent years, the market for exotic pets has greatly increased. This increase has resulted in transmission of several unusual organisms, such as exotic Salmonella spp., which are often associated with pet reptiles. Media attention was captured after an outbreak of monkeypox in America that affected >70 persons in 2003. After infected African rodents had been imported for the pet trade, the infection spread into native North American black-tailed prairie dogs and was subsequently disseminated among humans (32).

Bush Meat
Zoonotic diseases associated with hunting and eating wildlife is of increasing global concern. Bush meat is considered a delicacy by many and has resulted in its growth as a commercial enterprise. Tracking, capturing, handling, butchering in the field, and transporting of carcasses involve risks of cross-species transmission. Particularly high risks are associated with hunting nonhuman primates. The act of butchering is a greater risk factor for acquiring bloodborne pathogens than transporting, selling, and eating the butchered meat (33).

Zoonotic pathogens from wildlife may infect humans with little or no human-to-human transmission (e.g., avian influenza virus and Hendra virus). Alternatively, increased travel or migration and increased between-person contacts have facilitated emergence of simian immunodeficiency virus/HIV/AIDS in Africa. Increased exposure to wild-caught animals and high mutation rates of many RNA viruses have increased their predominance among emerging zoonoses transmitted from human to human; RNA viruses from bush meat may therefore play a possible role in future disease emergence.

Globalization and Livestock Movement
Large-scale movement of persons, livestock, food, or goods is now commonplace and provides increasing opportunities for rapid spread of pathogens. Trichinellae in horsemeat have been transported across the Pacific Ocean and infected consumers in other parts of the world. Discarded tires provide new habitats for mosquitoes in addition to their usual ecologic niches. The World Organisation for Animal Health and the Food and Agriculture Organisation implement strict control of animal movement. Transport of animals can result in mingling of different species in crowded and stressful conditions. This mingling can suppress immune responses to persistent infections and increase pathogen shedding. Under such circumstances, susceptible species can readily become infected (34).

Tourism
Tourism has exponentially increased in recent years. This finding has resulted in increasing numbers of imported zoonoses, such as a variety of rickettsial spotted fevers, brucellosis, melioidosis, genotype I hepatitis E (35), tick-borne encephalitis (36), and schistosomiasis (37).A rapid increase in cases of African tick bite fever has been associated with travelers to sub-Saharan Africa and the eastern Caribbean. This disease, which is caused by R. africae, is transmitted by a particularly aggressive Amblyomma sp. tick; >350 imported cases have been observed in recent years (31). Infection sequalae, such as subacute neuropathy, may be found long after travel when tick bite fever eschars have disappeared (37). An estimated >1 million international journeys are made each day, and a staggering 700 million tourists travel on an annual basis. Detailed travel histories of patients who show clinical signs and symptoms of disease are needed.

Changed Land Use and Urbanization
Deforestation and development of natural habitats have been seen on a global scale to accommodate intensification of agriculture and living areas for humans. As a result, ecologic habitats have been disrupted, reservoir abundance has changed, and transmission dynamics have been altered. Reduced host abundance may force vectors to seek alternative hosts, increasing opportunities for disease transmission, as demonstrated by increases in human cases of Lyme borreliosis, ehrlichiosis, spotted fevers, and anaplasmosis. Development of forests to provide rubber plantations in Malaysia has been correlated with increases in schistosomiasis (37). Wildlife may modify feeding practices as a consequence of changing land use, bringing them closer to humans and livestock. This modification was suggested to have been instrumental in the Nipah virus outbreak that affected pigs and humans in Malaysia in 1999. Nipah virus persists as a serious problem in many rural areas of Bangladesh and India, where infected bats living near human dwellings, urinate in date palm sap, which is later consumed raw by humans (38).

Human population growth has been associated with reshaping of population demographics. Increasing from 1 billion at the beginning of the 20th century to 6 billion by the end of the century, current predictions forecast a human population of ≈10 billion by 2050. This prediction is accompanied by a staggering increase in urbanization of the population from 39% in urban environments in 1980 to 46% in 1997 and a predicted 60% by 2030. This high-density clustering of the human population paves the way for potential outbreaks on an immense scale (5).

Public Health Risks of Reemerging and Neglected Zoonoses
Many areas are now experiencing a reemergence of zoonotic pathogens, partly resulting from collapse of public health programs during political upheavals. Often, these areas increasingly appeal to those seeking adventurous or unusual holiday destinations.

Delay in development of clinical signs and often insidious onset can challenge appropriate diagnosis and patient management. Furthermore, movements of animals used for agricultural trade, sport, and as companions also offer opportunities for further dissemination of infections. Brucellosis-free countries have seen reintroductions associated with movement of infected livestock. Movement of pets throughout Europe has been associated with an alarming increase in diseases such as leishmaniasis. Moreover, pets can harbor ectoparasites such as ticks, fleas, and lice. All of these parasites, especially ticks, are notorious vectors of multiple zoonotic agents.

We are at risk for airborne transmission of zoonoses by many factors (e.g., from travel to farms, consumption of food, and mowing the lawn, which as been associated with tularemia). Visiting petting farms or having family pets increases the likelihood of potential zoonotic infections, especially if pets are exotic. Water sports may increase the risk for acquiring leptospirosis. Wilderness camping activities have been associated with hantavirus infection after inhalation of aerosolized urine excretions of rodents. Other sporting activities such as hunting have been associated with brucellosis and tularemia. Travel to other countries opens a range of new potential zoonotic exposures through direct contact or indirectly through fomites, food, or arthropod vectors. Increasingly exotic locations are being sought with associated exotic zoonoses. Some tourists consume local delicacies, such as aborted animal fetuses in Ecuador, which are a source of brucellosis (39).

Conclusions and Future Prospects
Many zoonoses can be considered opportunistic infections. Increasing demands for protein necessitate increased levels of farming. Food can provide a vehicle for spread of pathogens from animals to humans. Contact with animals during farming, hunting, or by animal bites can increase transmission of diseases (e.g., rabies and tularemia). Arthropod vectors can transmit diseases on an immense scale to other hosts as in cases of West Nile fever and plague.

Changing patterns of farming, life style, and transportation influence the dynamics of pathogen ecology. Pathogens are subjected to changes by many intrinsic and extrinsic factors. Mutation, recombination, selection, and deliberate manipulation can result in new traits acquired by pathogens and result in potential epidemic consequences.

Reemergence of diseases through opportunistic host switching is likely to continue as a major source of human infectious disease. Strategies to improve public health have focused on improved surveillance in regions of perceived high likelihood of disease (reemergence). These strategies include improved detection of pathogens in reservoirs, early outbreak detection, broad-based research to identify factors that favor reemergence, and effective control (i.e., quarantine and improved hygiene) (40).

Figure

Figure. Factors influencing new and reemerging zoonoses.

To recognize and combat zoonotic diseases, the epidemiology of these infections must be understood. We need to identify pathogens, their vertebrate hosts, and their methods of transmission. Identification should include knowledge of spatiotemporal disease patterns and their changes over time. These features can be used to identify dynamic processes involved in pathogen transmission (Figure), which can be used to account for observed disease patterns and ultimately forecast spread and establishment into new areas.

Armed with information on expected disease patterns, we can address whether change has occurred beyond that which would normally be expected. However, this analysis may not be suitably responsive to control new and emerging zoonoses. Improved detection may be achieved through use of syndromic approaches rather than searching for specific pathogens.

Human disease surveillance must be associated with enhanced longitudinal veterinary surveillance in food-producing animals and wildlife. Prompt detection and instigation of control measures such as vaccination are pivotal to prevent disease spread. Novel molecular methods (e.g., DNA microarrays) offer unprecedented opportunities for rapid detection. However, these methods require optimization and validation before they can be used in routine microbiology laboratories. Cloned antigens or attenuated vaccines can be rapidly modified into appropriate antigenic forms. However, for identification of specific pathogens, more research will be needed to provide timely management of a new or emerging disease threat.

Approaches for identification of pathogen replication in vectors are more likely to offer substantial benefits for control of zoonoses. These methods are inappropriate for human vaccines, which must adhere to stricter legislative criteria. However, control of zoonotic infections in reservoir hosts has a pronounced protective effect in human populations. Use and development of antiviral drugs are other useful possibilities, but these drugs are likely to be too expensive for use in large disease outbreaks and emergence of drug resistance may result in concomitant loss of therapeutic options for these agents.

We do not know which zoonosis will be the next serious public health threat. However, as we increase efforts to improve the capacity to respond to this pathogen, we will also increase the likelihood that we can efficiently and effectively respond to new, reemerging, or neglected zoonoses in the future.

Acknowledgments
We thank Eric Fevré for helpful comments during the drafting of this manuscript and MedVetNet for support.

A.R.F. is supported by the United Kingdom Department for Environment, Food and Rural Affairs (Defra grant SEV3500).

Dr Cutler is a reader in microbiology and infectious disease at the School of Health and Bioscience of the University of East London. Her research interest is bacterial zoonoses, particularly Q fever, brucellosis, rickettsiosis, leptospirosis, and relapsing fever borreliosis.
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发表于 2010-6-20 22:14 | 显示全部楼层
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还是要提前采取相应的措施来预防人畜共患病吧,否则,到时候还不知道又会出现什么样的传染病!
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