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In
September and October, 2005, five alpacas were confirmed to have
been fatally stricken with Eastern Equine Encephalitis. Three
of these animals were from two different farms in south eastern
New Hampshire, the other cases were from New York and New
Jersey. NEAOBA and researchers from the Cummings School of
Veterinary Medicine at Tufts University conducted a limited
study in New Hampshire and New York during October to determine
the prevalence of natural antibodies against EEE in alpacas
living in areas with a high incidence of EEE associated death.
In November a proposal to conduct a trial of an equine EEE and
WEE vaccine in alpacas was approved for funding by the Alpaca
Research Foundation (ARF). This trial began in December, 2005
and concluded in early summer 2006 (see update below).
Eastern equine encephalitis is a rare but serious disease caused by
the Eastern equine encephalitis (EEE) virus, a member of the
family Togaviridae, genus Alphavirus. Eastern equine
encephalitis is found mainly along the eastern seaboard and Gulf
coast of the United States. EEE is a mosquito borne infection of
wild birds that can be transmitted to other birds, humans,
horses and other animals by mosquitoes.
Infection with Eastern equine encephalitis virus can cause a range
of illnesses. Most people infected with the virus have no
symptoms; others get only a mild flu-like illness with fever,
headache, and a sore throat. In rare cases, infection of the
central nervous system occurs, causing sudden fever, muscle
pains and a headache of increasing severity, often followed
quickly by seizures and coma. In these rare instances, about one
third of patients die from the disease. Of those who survive,
many suffer permanent brain damage. Clearly, it is hard to know
about mild cases in animals, but the severe neurological
effects, including death, are known to occur in some infected
horses (and now camelids).
Reported
clinical signs of EEE infection in llamas and alpacas are
consistent with brain (CNS) disease and may include dullness,
fever, incoordination, mentally inappropriate behavior,
seizures, inability to rise, persistent tilting of the head,
rapid eye movement and a swan-like backward flexion (opisthotonus)
of the head and neck. Unfortunately, there are no disease
specific findings for EEE infection, as these signs may mimic
other CNS and spinal problems such as West Nile Virus infection,
Equine Herpes Virus-1, rabies, trauma, bacterial meningitis,
Thiamine (Vitamin B1) deficiency, tick paralysis and meningeal
worm infection. Therefore, additional diagnostics such as a
spinal tap and blood analysis are commonly required to make a
diagnosis. To date, most reported cases have involved young
camelids.
The Eastern equine encephalitis virus has a complex life cycle
involving birds and a specific type of mosquito, Culiseta
melanura, which lives in acid water swamps. These mosquitoes
feed only on birds; they do not normally feed on humans or other
mammals.
Infected wild birds do not usually
become ill with the disease. The natural cycle for EEE virus
occurs nearly every year in some swamp habitats. In certain
years the virus may become amplified in this bird-mosquito
cycle, however, and other species of mosquitoes which feed on
both birds and mammals act as bridge vectors and are capable of
transmitting the virus to mammals, including horses and humans.
Late summer of 2005 was such a year, with an outbreak of EEE in
the north east causing several human fatalities in Massachusetts
and New Hampshire. In fall of 2005 the state of New Hampshire
was warning that 2006 could be as bad, or even worse.
Fortunately, the outbreak in 2006 was less extensive than the
one in 2005.
Prior to September, 2004, it was felt that camelids were not
infected by the EEE virus, but necropsy of an alpaca at the
Cummings School of Veterinary Medicine at Tufts University at
that time confirmed EEE as the cause of death. In the course of
preparing a publication on this case, researchers at Tufts
discovered several other cases where EEE had been confirmed as
the cause of death in camelids. The fact that alpacas were (and
are) at risk from EEE was not widely disseminated; early in the
2005 outbreak described below the International Camelid
Initiative (at Ohio State University) was strongly asserting
that camelids could not be infected.
In late
September, 2005 a cluster of cases raised the visibility of EEE
in alpacas significantly. Four animals from three different
farms in south eastern NH presented to a single veterinary
practice within a 2 week period. The first case was a 10 day
old cria that had progressed to recumbency and seizures before
reaching the vet. This animal died soon after being admitted to
the clinic, no postmortem analyses were conducted. However,
when a 16 day old cria from a nearby farm presented at the same
clinic with similar symptoms, alarm bells went off and intensive
supportive measures were initiated. Despite these efforts, case
2 succumbed within 48 hours. Days later cases 3 (another cria
from a third farm) and 4 (healthy yearling from same farm as
case 2) also presented at the same clinic. These animals died
within 4 and 3 days, respectively. PCR analysis (polymerase
chain reaction, a DNA test) of brain tissue from cases 2-4
confirmed EEE for all cases, The first death is also suspected
to be due to EEE but was never confirmed.
During this
period the NEAOBA board of directors initiated several efforts
to learn more about EEE in camelids. First step was to
ascertain whether the outbreak was localized or more
widespread. Mass emails to all NEAOBA members requested
“private” reporting of any similar cases. This revealed one
additional fatal EEE case in an alpaca from central New York, as
well as a cria in south western NH that displayed neurological
problems including seizure, but survived. Analysis of serum
from this animal subsequently confirmed high titer of EEE
antibodies. It was also during this time that NEAOBA learned of
the earlier cases at Tufts and established initial contact with
Dr. Daniela Bedenice (also Drs. Karen Baum and Patricia Craven,
members of the ARF BOD).
News of the
outbreak spread beyond the north east through forwarded email
messages and several of the industry chat sites. In October a
breeder in New Jersey reported that a breeding male had died
from EEE, in this case the attending vet felt that stress from
elective surgery had weakened the animal’s immune system and
made it easier for the virus to overcome his defenses.
NEAOBA
decided to launch two studies, in collaboration with Dr.
Bedenice and Dr. Amy Bright (a clinical vet at the practice that
treated the four cases in south east NH described above). To
establish seroprevalence (fraction of the population with
natural antibodies) of EEE antibodies in naturally exposed
alpacas we collected serum samples on the 22nd of
October from 14 surviving animals on the NY farm that lost an
animal to EEE, 27 survivors on the two NH farms that suffered
losses, and 46 animals living on 4 different NH farms that were
within 10 miles of the impacted farms. Serum neutralization (by
PRNT) tests were conducted at the US Department of Agriculture
National Veterinary Services Laboratory (NVSL). The
seroprevalence of EEE antibodies (PRNT titer > 1:10) was as high
as 29% on one of the farms with an overall prevalence of 10% in
this study.
The second
study is the vaccine trial, “Humoral response to EEE vaccination
in healthy alpacas” supported by ARF. Dr. Daniela Bedenice is
the Principal Investigator, collaborating researchers include:
Jack Dibb, NEAOBA treasurer, Drs. Tim Fallon and Amy Bright,
Cornerstone Vet Hospital, and Dr. Doug Pedersen, NVSL. NEAOBA
breeders provided 39 subject animals, spread between two farms
in Maine, two farms in NH and one in Vermont. We selected a
bivalent (eastern and western equine encephalitis) inactivated
vaccine because no monovalent EEE vaccines are currently
commercially available. Dr. Craig Barnett at Intervet arranged
for donation of the Intervet vaccine sold as Encevac™.
Specific objectives declared in the proposal are
reproduced here:
1.
Evaluation of EEE serum-antibodies via a
semi-quantitative
plaque
reduction neutralization test (PRNT) following 3 intramuscular
vaccinations with Encevac™ at 4-week intervals in 45 healthy
alpacas.
2.
Assessment of local and systemic reactions following EEE
vaccination.
We
hypothesized that alpacas would develop virus-neutralizing
antibody titers similar to those reported in horses following
repeated EEE vaccination.
In plainer
English, objective 1 is to determine whether the vaccine leads
to antibody titers that are similar to those proven to provide
protection against EEE infection in other animals and objective
2 states that we want to be sure the vaccine has minor or no
side effects. It is important to recognize that this trial
did not intend to prove that the Encevac™ vaccine is
actually protective against EEE virus infection in alpacas,
since proving this would require deliberately exposing
vaccinated animals to the live virus. Such a study would have to
be performed on a small scale in specialized and approved
facilities due to the risks involved when working with the EEE
virus.
As noted in
the objectives, each subject animal received an initial
vaccination, followed by boosters 4 and 8 weeks later. Serum
samples were collected immediately before the first vaccination,
and then at 2 week intervals for a total of 12 weeks
February 2007
update:
The EEE
vaccine trial ended as planned in mid March, 2006 with final
results from the lab received in June. A manuscript describing
the detailed findings is in preparation. Dr. Bedenice has
agreed that this summary should be provided now, for breeders
and their veterinarians to consider.
One firm
finding was that the vaccine appeared to be safe in the adult
males tested, with no adverse reactions reported in any of the
subject animals. Just over three quarters of the trial animals
developed titers after the three shot series, with the highest
number of seropositive animals, and highest mean titers,
observed 2 weeks after the third shot. Younger (less than 4
years old) animals in the trial tended to respond “better” than
older animals, but the sample size was limited, especially for
the older groups
Drs. Bedenice
and Bright recommended that farms in high risk areas strongly
consider vaccinating in 2006, and several in NH took this advice
(including the two farms with all of the animals that developed
titers in Fall 2005 from natural exposure). Several hundreds of
additional serum samples were privately analyzed for EEE
antibodies at NVSL through the summer and fall of 2006. They
may be of interest because, unlike the trial, they included
pregnant females and neonates. The number of animals was small,
and the timing of sample collection could not ensure that
additional natural exposure to EEE had not caused antibody
responses, so the findings are unlikely to pass peer review.
However, I offer them to the community.
We resampled
the naturally exposed animals several times through late 2005
and up to June of 2006. In all cases where the alpacas had
developed titers higher than 1:100 when first sampled in
October, 2005 they maintained titers at this level or higher
through June, 2006. (Most were then vaccinated to boost their
immunity prior to peak mosquito season.)
One of the
naturally exposed females delivered a healthy cria in late May,
the cria had a positive titer (1:100) at 9 days of age (we
presume the antibodies came from mom, since it was very early in
the year for this animal to have been exposed to the live
virus).
A total of 29
breeding females and their 2006 cria were vaccinated on the 2 NH
farms that owned all of the animals with natural antibodies to
EEE in 2005 (these farms were clearly at “high risk”). Ten of
the females were relatively advanced in their pregnancies, but
none reacted adversely to the 3 shot series. Nine of them
delivered healthy full term cria during the summer and fall (the
tenth lost a breech delivery at term).
Results of
PRNT on serum samples collected 3.5 to 4.5 months after the
first shot (for animals that were negative in fall 2005) were
broadly similar to the formal trial. Overall, 65% of the
vaccinated animals developed titers and maintained them at least
until they were sampled about 2 months after final booster.
Like the males in the trial, measurable responses (titers) were
less common, and lower when found at all, in the oldest girls.
Neonates
(first shot given 3-5 weeks post partum) as a group also
responded poorly, compared both to the young boys in the trial
and the younger breeding girls in their herds. The cria that
had the presumed natural titer, transferred from mom, at 9 days
of age tested negative at 6 months of age, despite receiving a
4-shot vaccination series. Pat Long, DVM and ARF treasurer,
speculates that the maternal antibodies may be antagonistic to
the vaccine, and recommends waiting till 3 months of age before
vaccinating crias, especially if mom is known to be seropositive.
We are deeply
appreciative of the support provided by NEAOBA members during
the seroprevalence study, and thank the farms (Crown Point
Alpacas, Milesview Alpacas, Ande’s Acres Farm, Cynjim Alpacas,
Fraggle Rock Farm, Tamarack Meadow Farm, Sallie’s Fen Alpacas)
that allowed serum to be collected from their animals. The
vaccine trial would not have been possible without the financial
support of ARF, but the willingness of NEAOBA breeders to
provide subject animals for the study was also critical (special
thanks to New Aim Farm, Half Horse Farm, Cas Cad Nac, Cynjim
Alpacas, Tamarack Meadow, Crown Point Alpacas, A Craftman’s
Touch Alpacas and Sallie’s Fen Alpacas). Drs. Tamy Doty and Amy
Bright donated their time to vaccinate and collect samples from
the test groups in Maine and New Hampshire, and Ian and Jennifer
Lutz took care of the group from their farm. ARF exists solely
to support research into issues impacting alpacas and their
caregivers, and depends on donations to fund this important
work.
An earlier
version of this article was previously printed in Alpacas
Magazine |
