quadgram

This is a table of type quadgram and their frequencies. Use it to search & browse the list to learn more about your study carrel.

quadgram frequency
of feline infectious peritonitis265
no disclosures to report168
feline infectious peritonitis virus159
of this study was88
this study was to84
in cats with fip79
the aim of this73
with feline infectious peritonitis67
feline infectious peritonitis in62
in dogs and cats60
at the time of59
aim of this study55
diagnosis of feline infectious54
in feline infectious peritonitis46
of cats with fip43
infectious peritonitis virus infection42
from cats with fip40
the development of fip36
detection of feline coronavirus35
the central nervous system35
samples from cats with35
for feline infectious peritonitis34
for the diagnosis of34
the diagnosis of feline33
for the detection of31
included in the study31
the diagnosis of fip31
in the present study31
as a result of30
were included in the30
pathogenesis of feline infectious30
in the diagnosis of30
of feline enteric coronavirus29
in the pathogenesis of28
study was to evaluate28
is the most common28
cats with feline infectious27
feline infectious peritonitis feline26
the detection of fcov26
to feline infectious peritonitis26
infected cats without fip26
cats with and without25
it is important to23
occurring feline infectious peritonitis22
naturally occurring feline infectious22
peritonitis feline infectious peritonitis22
infectious peritonitis feline infectious21
infected with feline coronavirus21
of naturally occurring feline21
the objective of this20
transcriptase polymerase chain reaction20
the aim of the20
diseases other than fip20
from cats without fip19
of dogs and cats19
the present study was19
lesions in feline infectious19
on the other hand19
in the treatment of19
lesions consistent with fip19
are more likely to19
study was to determine19
infectious peritonitis in cats18
feline infectious peritonitis and18
strains of feline infectious18
in the absence of18
has been reported in18
the most common cause18
of the present study18
one of the most18
was to evaluate the18
cats with fip and18
used in this study18
was found to be17
for the presence of17
of fcov antigen in17
more likely to be17
the pathogenesis of fip17
the time of diagnosis17
samples from cats without17
in the development of17
dose of mg kg17
with and without fip17
against feline infectious peritonitis17
in a cat with17
and feline enteric coronavirus17
of cats with feline17
to the development of17
of feline coronaviruses in16
of feline coronavirus in16
dogs and cats with16
feline infectious peritonitis among16
coronavirus feline infectious peritonitis16
most common cause of16
arise by mutation from16
a review of feline16
play a role in16
endemic feline enteric coronaviruses16
of the small intestine16
infectious peritonitis among cats16
by mutation from endemic16
from endemic feline enteric16
mutation from endemic feline16
review of feline infectious16
feline infectious peritonitis viruses15
severe acute respiratory syndrome15
feline infectious peritonitis detection15
cats with hepatic lipidosis15
can be used to15
to diagnose feline infectious15
infectious peritonitis viruses arise15
with areas of necrosis15
diagnose feline infectious peritonitis15
effusions of cats with15
tissue samples from cats15
viruses arise by mutation15
types i and ii15
infectious peritonitis detection of15
cell differentiation survival factors15
peritonitis viruses arise by15
in cats without fip15
the pathogenesis of feline15
feline enteric coronavirus infection15
of naturally infected cats15
analysis was performed using15
may be associated with15
reverse transcriptase polymerase chain15
in the presence of15
cats with fip were14
in the course of14
detection of feline coronaviruses14
study was to assess14
a retrospective study of14
has been shown to14
were significantly lower in14
objective of this study14
feline enteric coronavirus and14
the purpose of this14
feline infectious peritonitis by14
was no significant difference14
a large number of14
in the case of14
granulomas with areas of14
as well as the14
there was no significant14
sequence analysis of the14
mg kg po q14
experimentally induced feline infectious13
a complete blood count13
peripheral blood mononuclear cells13
the effusive form of13
related strains of feline13
of feline coronavirus rna13
in the central nervous13
was to determine the13
feline infectious peritonitis using13
and body fluids of13
feline infectious peritonitis the13
two related strains of13
associated with feline infectious13
in any of the13
presence or absence of13
faecal samples from cats13
definitive diagnosis of fip13
at the university of13
sensitivity and specificity of13
risk factors for feline13
in this study was13
a definitive diagnosis of13
induced feline infectious peritonitis13
feline coronavirus infections in13
enhancement of feline infectious13
present study was to13
little is known about13
naturally infected cats by12
and immunologic aspects of12
infected cats by reverse12
to be associated with12
cats by reverse transcriptase12
of fcov rna in12
the presence of fcov12
of the placebo group12
of the s protein12
feline infectious peritonitis date12
fluids of naturally infected12
for the development of12
in the control group12
for diagnosis of feline12
of cats suffering from12
the course of the12
has been reported to12
consistent with fip in12
virologic and immunologic aspects12
statistical analysis was performed12
body fluids of naturally12
from immunocompromised cats infected12
cats infected with a12
consistent with fip were12
are shown in table12
a dose of mg12
immunocompromised cats infected with12
immunologic aspects of feline12
coronavirus rna in feces12
cats and cats with12
aim of the present12
feline coronavirus rna in12
was found in the12
in the spike protein12
in the effusive form12
aspects of feline infectious12
by reverse transcriptase pcr12
isolated from immunocompromised cats12
have been shown to12
study was to investigate12
the dog and cat12
samples from healthy cats12
on the basis of11
and feline infectious peritonitis11
dependent enhancement of feline11
infected with a feline11
with inflammatory bowel disease11
an overview of feline11
the incidence of fip11
of their diagnostic value11
intestinal small cell lymphoma11
if the cat is11
and the presence of11
virus isolated from immunocompromised11
assessment of their diagnostic11
included in this study11
plasma protein binding of11
this is the first11
infectious peritonitis virus in11
kg po q h11
a small number of11
infectious peritonitis virus isolated11
infectious peritonitis in a11
liver disease in cats11
overview of feline enteric11
cats feline infectious peritonitis11
feline infectious peritonitis a11
cats in this study11
a role in the11
statistically significant difference in11
peritonitis virus isolated from11
medical records of dogs11
infectious peritonitis and feline11
a feline enteric coronavirus11
factors for feline infectious11
detection of fcov antigen11
critical assessment of their11
in cats with chronic11
with central neurologic disease11
in of cats with11
during the study period11
in at least one11
is one of the11
the m l substitution11
cats naturally infected with11
infectious peritonitis virus infections11
of the spinal cord11
tissue and fecal samples11
with a feline enteric11
naturally occurring feline coronavirus10
in the c gene10
and infectious peritonitis virus10
feline coronavirus spike protein10
the distribution of the10
role in the pathogenesis10
cats with naturally occurring10
spf and fip cats10
was added to the10
a review of clinicopathological10
funded by royal canin10
of cats without fip10
the viral spike protein10
s gene mutations in10
healthy cats and cats10
and pathological findings in10
of clinicopathological changes in10
cells positive for coronavirus10
detection of fcov rna10
pathological findings in cats10
of specific antibodies in10
in the a orf10
protein of feline coronavirus10
amino acid changes in10
dogs of other breeds10
this study aimed to10
have been associated with10
the challenge stock virus10
from healthy cats and10
peritonitis and feline enteric10
review of clinicopathological changes10
purpose of this study10
no significant difference in10
acid changes in the10
been shown to be10
may or may not10
structural and accessory genes10
the goal of this10
serologic studies of naturally10
it is not known10
susceptibility to feline infectious10
form of feline infectious10
clinicopathological changes in cases10
feline enteric coronavirus infections10
by feline infectious peritonitis10
were obtained from the10
with the exception of10
coronavirus and infectious peritonitis10
course of the disease10
in the majority of10
dogs with and without10
and baff mrna expression10
the treatment of choice10
with clinical signs of10
enteric coronavirus and infectious10
and a critical assessment10
in the fip group10
polymerase chain reaction of10
of the s gene10
spike protein of feline10
the spike protein of10
the end of the10
studies of naturally occurring10
the detection of feline10
time of first vaccination10
feline coronavirus type i10
the non fip group10
naturally infected with feline10
the time of first10
clinical and pathological findings10
and feline immunodeficiency virus10
in cats naturally infected10
correlation was found between10
a critical assessment of10
experimentally infected with feline9
specific antibodies in lesions9
transcription unit of different9
of the cats with9
analysis of the orf9
cats and its relationship9
on feline infectious peritonitis9
coronavirus antigen expression and9
of the gastrointestinal tract9
was to assess the9
comparative sequence analysis of9
been reported in cats9
of the dog and9
and phylogenetic analysis of9
coronavirus type i and9
with systemic spread of9
and a specificity of9
using a commercially available9
and its relationship to9
in cats experimentally infected9
this retrospective study was9
expression and production of9
a b transcription unit9
of the orf a9
peritonitis among cats in9
polymerase chain reaction for9
deletions in the a9
at a dose of9
there was no difference9
of a modified live9
of humoral and cellular9
as well as in9
per cent of cats9
resistance of feline peritoneal9
peritonitis detection of feline9
a total of dogs9
by mutations in the9
a study of naturally9
studies are required to9
without feline infectious peritonitis9
in cats with severe9
occurring feline coronavirus infections9
risk of feline infectious9
by the presence of9
the vaccine and placebo9
and production of specific9
relationship to feline infectious9
coronavirus infections in kittens9
of this retrospective study9
is likely to be9
peritoneal and pleural effusions9
school of veterinary medicine9
in cats with hepatic9
goal of this study9
production of specific antibodies9
feline peritoneal macrophages to9
the molecular genetics of9
changes consistent with fip9
could not be determined9
to mg kg day9
was approved by the9
small and large intestine9
phylogenetic analysis of feline9
humoral and cellular immunity9
its relationship to feline9
unit of different biotypes9
study was to compare9
can be found in9
antigen expression and production9
of the dogs were9
important role in the9
can be detected in9
suspected of having fip9
orf a b transcription9
the small and large9
intrinsic resistance of feline9
of cats and its9
prevalence of fip in9
peritonitis in cats naturally9
the orf a b9
from the same cat9
molecular genetics of feline9
the presence of coronavirus9
blood samples from healthy9
b transcription unit of9
from dogs and cats9
as a consequence of9
study was approved by9
the length of the9
have been described in9
tests in the diagnosis9
study of naturally occurring9
cats experimentally infected with9
of feline peritoneal macrophages9
tested positive for fcov9
cats suspected of having8
from the feces of8
the sensitivity of the8
but not in controls8
prevalence of hcm in8
and can be used8
epidemiology of feline infectious8
diagnosis of fip is8
and pathogenesis of feline8
of the elfa in8
cats are more likely8
of cats with suspected8
of laboratory tests in8
a common cause of8
the cause of the8
cats with confirmed fip8
some aspects of humoral8
cats were included in8
have not yet been8
a sensitivity of and8
in all cats with8
endemic feline enteric coronavirus8
cats with lgl lymphoma8
the results of the8
with the aim to8
and cellular immunity in8
in lesions in feline8
inheritance of susceptibility to8
coronavirus infection of cats8
samples were collected from8
aspects of humoral and8
diseased tissues of cats8
suspected feline infectious peritonitis8
diagnosis of fip was8
antibodies in lesions in8
neurologic feline infectious peritonitis8
the right pulmonary artery8
it is appropriate to8
of the disease and8
cats with fip exhibit8
cats with effusive fip8
as well as to8
ck isoenzymes and macroenzymes8
the presence of the8
macrophages to coronavirus infection8
of the tissue samples8
was not significantly different8
glycoprotein in the diagnosis8
be detected in the8
at mg kg po8
of this prospective study8
a commercially available kit8
of the presence of8
are summarized in table8
cats with immunohistochemically confirmed8
to years of age8
or a combination of8
important to note that8
an important role in8
codon was identified in8
in the mes lnn8
effusive form of fip8
for the first time8
the presence or absence8
no statistically significant difference8
laboratory tests in the8
a statistically significant difference8
of the tricuspid valve8
protection against feline infectious8
with fip in cats8
should be performed in8
this prospective study was8
be found in the8
environments with endemic feline8
the use of a8
have been reported in8
with diseases other than8
was no difference in8
the majority of dogs8
with in vivo virulence8
the nature of the8
diagnosis was based on8
strains of fip coronavirus8
our results suggest that8
of s gene mutations8
during the pathogenesis of8
an enteric coronavirus infection8
a suspicion of fip8
peritonitis in purebred catteries8
with immunohistochemically confirmed fip8
to confirm the diagnosis8
effusive form of feline8
dogs and cats were8
cat environments with endemic8
for detection of feline8
further studies are required8
fcov antigen in macrophages8
the vaccine group and8
diseases of the dog8
in the placebo group8
it has been suggested8
a diagnostic test for8
demonstration of feline infectious8
clinical diagnosis of fip8
infection of feline macrophages8
peritoneal macrophages to coronavirus8
with endemic feline enteric8
iwhs with previous bp8
the feline coronavirus spike8
in cats with a8
enteric coronavirus infection of8
dogs were included in8
in the brains of8
pathologic changes and immunofluorescence8
is associated with a8
at the level of8
infectious diseases of the8
i and canine coronavirus8
feline coronavirus feline infectious8
the prevalence of the8
for up to days8
analysis of the viral8
a leucine codon was8
mesenteric lymph nodes and8
may be required to8
in the feline coronavirus8
as a diagnostic test8
infectious peritonitis in purebred8
infection of cats and8
were more likely to8
genetics of feline coronaviruses8
acid glycoprotein in the8
study was to describe8
the cats with fip8
among cats in multiple8
cats with fip had8
fcov s gene mutations8
in the lymph nodes8
cats with histopathologically confirmed8
of susceptibility to feline8
changes in the spike8
of the central nervous8
clinically normal and fip7
in peripheral blood monocytes7
peritonitis is determined by7
should be performed to7
the amino acid sequence7
of the genomes of7
and not with feline7
high viral loads despite7
is an employee of7
is important to note7
the study was approved7
infectious peritonitis in specific7
has also been reported7
peritonitis virus infection in7
aim of this prospective7
the inheritance of susceptibility7
not consistent with fip7
in cats with histopathologically7
there was a significant7
at months of age7
coronavirus infection correlates with7
on the survival time7
infectious peritonitis is determined7
cats infected with feline7
of the university of7
higher viral loads than7
loads despite absence of7
retrospective study was to7
and cats with central7
these results suggest that7
cats without fip symptoms7
coronaviruses and their evolution7
in a previous study7
in feline macrophages by7
the small number of7
persistence and evolution of7
reaction of blood samples7
is most commonly associated7
of feline coronaviruses by7
the mesenteric lymph nodes7
spike protein fusion peptide7
the majority of the7
chronic mitral valve disease7
a high rate of7
by far the most7
small number of cats7
clinical signs associated with7
sensitivity of and a7
can be associated with7
is considered to be7
fusion peptide and feline7
were included in this7
were not included in7
mutations in the feline7
cats with central neurologic7
of the detection of7
culture and reverse transcriptase7
of a cat with7
of the study was7
of cats with confirmed7
during the course of7
in the faeces of7
of cats in the7
of recombinant feline interferon7
most commonly associated with7
was the most common7
to coronavirus infection correlates7
histological lesions consistent with7
results of this study7
has not been reported7
between feline coronaviruses and7
of the challenge stock7
is determined by mutations7
and in naturally fcov7
cats of the placebo7
with feline immunodeficiency virus7
the diagnostic value of7
feline infectious peritonitis after7
comparison of the genomes7
by culture and reverse7
history and clinical signs7
at veterinary medical teaching7
age at the time7
the intestine and not7
not with feline infectious7
the underlying cause of7
the clinical signs of7
a premature stop codon7
in the small intestine7
coronavirus in a closed7
for the treatment of7
and evolution of feline7
in cats with feline7
evolution of feline coronavirus7
to the presence of7
despite absence of clinical7
protein fusion peptide and7
play an important role7
from the intestine and7
a median age of7
fip and spf cats7
from a cat with7
over a period of7
absence of clinical and7
at the end of7
determined by mutations in7
findings in cats with7
of and a specificity7
of blood samples from7
diagnosis is based on7
baff mrna expression levels7
and feline coronavirus virulence7
and months of age7
the results of this7
were used in this7
gene of feline infectious7
coronaviruses by culture and7
is reported to be7
is involved in the7
immunologic phenomena in the7
phenomena in the effusive7
has been suggested that7
coronavirus correlate with systemic7
it is possible that7
infection in feline macrophages7
cats with clinical signs7
a comparison of the7
of feline coronavirus correlate7
acquisition of macrophage tropism7
high pressure liquid chromatography7
the university of bristol7
detection of s gene7
feline coronavirus correlate with7
feline infectious peritonitis coronavirus7
what they tell us7
these findings suggest that7
spread of virus from7
for the measurement of7
at the same time7
was used to compare7
of clinical and pathological7
clinical signs consistent with7
the development of the7
with clinical feline infectious7
cats with clinical feline7
potentially consistent with fip7
findings in cats experimentally7
treatment of choice for7
correlate with systemic spread7
viral loads despite absence7
the plasma protein binding7
infection correlates with in7
genomes of fecvs and7
must be differentiated from7
type i feline coronavirus7
involved in the pathogenesis7
this study were to7
the genomes of fecvs7
analysis based on the7
of this study is7
was significantly higher in7
feline pancreatic lipase immunoreactivity7
feline coronaviruses and their7
of this study were7
systemic spread of virus7
feline coronavirus antibodies in7
type i and canine7
veterinary medical teaching hospitals7
feline immunodeficiency virus infection7
for use in cats7
feline infectious peritonitis is7
in one study of7
update on feline infectious7
and mesenteric lymph nodes7
cellular immunity in naturally7
tests to diagnose feline7
feline coronaviruses by culture7
in cats affected by7
the level of the7
in specific cat breeds7
type i and in7
that died of fip7
tropism during the pathogenesis7
from feline infectious peritonitis7
aim of the study7
they tell us about7
different tests to diagnose7
in of the cats7
clinical feline infectious peritonitis7
of different tests to7
studies are needed to7
an update on feline7
of macrophage tropism during7
intestine and not with7
test for feline infectious7
correlates with in vivo7
feline coronavirus in a7
a linear foreign body7
of virus from the7
peptide and feline coronavirus7
onset of clinical signs7
chain reaction of blood7
viral loads than healthy7
and cats with clinical7
in the amount of7
blood samples from cats7
form of the disease7
the study was to7
macrophage tropism during the7
the presence of a7
with the effusive form7
to be the most7
comparison of different tests7
i and in naturally7
virus from the intestine7
the median survival time7
the time of exposure6
significantly higher viral loads6
there was no statistically6
sequence of feline coronavirus6
and the development of6
diagnostic test for feline6
the prevalence of hcm6
in the vaccine group6
disease in the cat6
cats with neurological signs6
hba c in dogs6
and complement activity fluctuations6
of the value of6
than years of age6
epidemic of feline infectious6
reference on page for6
of fcov s gene6
acute spinal cord injury6
assay for detection of6
is believed to be6
of fip in the6
quantitatively analyzed in terms6
examined at veterinary medical6
the four related cats6
of feline coronavirus strain6
of the feline coronavirus6
the value of laboratory6
tell us about the6
used in the diagnosis6
vaccine and placebo group6
in kittens with experimentally6
samples were obtained from6
coronavirus antibodies in cats6
of the infected cats6
type of feline lymphoma6
vincristine were detected on6
the cat should be6
and epidemiology based on6
infectious peritonitis by intranasal6
of coronavirus mutants in6
of cats diagnosed with6
significant difference in the6
used in cats with6
the fcov zu strain6
type i and ii6
with small cell lymphoma6
infiltration of neutrophils into6
tissues of cats with6
in effusions of cats6
lower esophageal sphincter tone6
the prevalence of anemia6
of serotype ii feline6
of the viral c6
cats with suspected feline6
mg kg q h6
of the right pulmonary6
with suspected feline infectious6
main reference on page6
of different diagnostic tests6
was carried out in6
were positive for the6
likely to occur in6
diagnosis of fip in6
in cats with effusive6
coronaviruses feline infectious peritonitis6
are likely to be6
not included in the6
of spinal cord dysfunction6
a methionine codon was6
genomic rna sequence of6
in the gastrointestinal tract6
detected on the floor6
were excluded from the6
and diastolic rv function6
in the bone marrow6
m l and s6
value of laboratory tests6
to determine the prevalence6
feline infectious peritonitis pathogenesis6
cipf whwts but not6
feline coronavirus pathobiogenesis and6
rna sequence of feline6
antigen in macrophages in6
veterinary teaching hospital of6
the effusions of cats6
l and s a6
coronavirus mutants in feces6
on page for details6
feline coronavirus type ii6
the majority of cases6
determine the prevalence of6
leads to a premature6
that the detection of6
of feline coronavirus infection6
the infiltration of neutrophils6
in some cats with6
a veterinary teaching hospital6
was identified in samples6
fip exhibit significantly higher6
some important disorders of6
only in cats with6
of ck isoenzymes and6
analyzed in terms of6
loads than healthy infected6
cytokine transcription levels in6
the d l value6
significance of coronavirus mutants6
were significantly associated with6
in the management of6
the sequences encoding for6
traces of vincristine were6
in a series of6
cats with fip in6
i feline coronavirus infection6
be responsible for the6
should be ruled out6
identified in samples from6
among cats examined at6
exhibit significantly higher viral6
with the development of6
is not possible to6
and mesenteric lymph node6
in feces and diseased6
of the information found6
may be seen in6
systolic and diastolic rv6
between feline coronavirus type6
feces of healthy cats6
into feline coronavirus pathobiogenesis6
based on the sequences6
in this study we6
the s gene mutations6
a combination of these6
did not differ significantly6
a cat with feline6
rna was extracted from6
of the pathogenesis of6
is more likely to6
higher than those of6
cat with feline infectious6
excluded from the study6
feline infectious peritonitis two6
of these cats were6
virus infection in feline6
were used to assess6
to identify intracellular organisms6
associated with cardiac injury6
fecal s a concentrations6
with fip exhibit significantly6
brain and spinal cord6
in peritoneal and pleural6
did not differ between6
peritonitis in specific cat6
of neutrophils into granulomatous6
and cytokine responses in6
did not show any6
consisted of cats with6
in a closed cat6
low intensity of positivity6
is a fatal disease6
prospective study was to6
based on genetic analysis6
epidemiology based on genetic6
important disorders of cats6
in serum and in6
mutants in feces and6
acute phase proteins in6
between fecv and fipv6
cats suffering from feline6
prednisolone at mg kg6
west highland white terriers6
the measurement of hba6
mrna expression levels in6
vascular lesions in feline6
the cells were washed6
number of differences per6
the lower esophageal sphincter6
suffering from feline infectious6
recombination between feline coronavirus6
injection of primary vaccination6
test was used to6
activity fluctuations in kittens6
on the sequences encoding6
it can be concluded6
was to investigate the6
healthy dogs and cats6
fluctuations in kittens with6
see main reference on6
intranasal inoculation of a6
per cent of all6
systemic spread of fcov6
was no statistically significant6
in cipf whwts but6
kittens with experimentally induced6
neutrophils into granulomatous lesions6
in cats with liver6
the number of cd6
were detected on the6
a double recombination between6
feline infectious peritonitis an6
of the immune system6
treatment of cats with6
of fecvs and fipvs6
similar to that of6
pancreatitis and cardiac injury6
should be treated with6
than or equal to6
role in the development6
of the viral spike6
from a double recombination6
approximately per cent of6
was detected in the6
more likely to develop6
with a sensitivity of6
more likely to have6
cent of cats with6
all other type of6
of cats against feline6
cats with fip but6
phylogenetic analysis based on6
in approximately of cases6
cats with diseases other6
consistent with fip if6
cats that died of6
the veterinary teaching hospital6
genetic analysis of the6
used to assess the6
of dogs with ibd6
complement activity fluctuations in6
double recombination between feline6
is commonly used in6
the prepatent period is6
in all of the6
feline infectious peritonitis with6
protein binding of mefloquine6
on genetic analysis of6
of the vaccine group6
strong intensity of positivity6
myxomatous mitral valve disease6
insights into feline coronavirus6
with intestinal small cell6
whwts but not in6
than healthy infected cats6
precision of the bcs6
median survival time of6
is an important step6
more likely to occur6
mean number of differences6
on the surface of6
evaluation of a modified6
does not appear to6
compared with those of6
is shown in figure6
of mouse hepatitis virus6
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coagulation in experimentally induced5
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nested pcr assay for5
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financial remuneration and gifts5
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appraisal of the value5
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the university of liverpool5
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development of a nested5
replication of feline coronaviruses5
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there appears to be5
center for companion animal5
elsewhere in this chapter5
feline coronavirus c gene5
monoclonal antibody against the5
and response to treatment5
described in the literature5
any of the cats5
may occur as a5
findings associated with feline5
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readership is funded by5
interpretation of feline coronavirus5
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the a orf of5
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a summary of the5
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recombinant feline interferon and5
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an acute phase protein5
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also be detected in5
the sequence of the5
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less than or equal5
was performed using the5
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clinics of north america5
detection of fcov s5
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american college of veterinary5
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international feline coronavirus feline5
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feline coronavirus infection and5
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coronavirus type ii strains5
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the medical records of5
virus antigen in paraffin5
a control group of5
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the severity of the4
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arises by mutation from4
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pathological and immunohistochemical findings4
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pathogenic differences between various4
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protein of feline infectious4
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lung disease mainly affecting4
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the elfa in dogs4
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a diagnosis of fip4
the distribution of viral4
analysis of feline coronavirus4
percentage change in diameter4
cardiac injury in dogs4
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diagnostic accuracy of the4
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a good agreement between4
nutritional status in small4
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the precision and accuracy4
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the most common feline4
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detect fcov antigen in4
occurring chronic kidney disease4
feline coronavirus mutations in4
coronaviruses with small deletions4
a mouse monoclonal antibody4
diagnosed as bcs of4
samples from fip cats4
term exposure to fip4
acute phase protein and4
mutation in spike protein4
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the information found online4
acute pancreatitis in cats4
serum ccl concentrations and4
were examined at the4
degeneration of the tricuspid4
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because of the presence4
viral antigen was detectable4
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for type ii and4
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sites of feline coronavirus4
feline infectious peritonitis comparison4
records of dogs presented4
role of igg subclass4
of takano et al4
persistence and transmission of4
hypothesis of this study4
natural feline coronavirus infection4
immunized with an avirulent4
diagnostic features of clinical4
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mesenteric lymph node and4
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status in small animals4
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the study design was4
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change over time ranging4
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the second international feline4
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pcr detecting s gene4
increased concentrations of crp4
in cmt progression and4
clustered with type i4
the mean angle between4
experimental feline infectious peritonitis4
after virus adsorption at4
and tumor necrosis factor4
the fcov zu and4
of the samples from4
in some acute phase4
the imidapril and placebo4
human patients with osas4
min in the imidapril4
was present only in4
coronavirus persistence in healthy4
age at diagnosis was4
is rare in cats4
phase of the disease4
likely to be diagnosed4
were present in the4
cats that developed fip4
resolution of clinical signs4
infection and fecal shedding4
small deletions in orf4
the efficiency of the4
were used for duplicate4
more than one organ4
genomic organization and expression4
limit of reference range4
staining of fcov antigen4
in samples from fip4
of cats that were4
dogs were included into4
survival time of cats4
infectious peritonitis evaluation of4
dogs were mixed breed4
detection of fcov antibodies4
between and months of4
codon at this position4
in dogs with imha4
it is not clear4
peritonitis in challenging clinical4
in the imidapril and4
and french beauce shepherd4
of the center for4
the nine structural and4
the majority of fcov4
in dogs with leishmaniosis4
fecal shedding from cats4
only treatment for sinonasal4
feline infectious peritonitis diagnostic4
incidence of fip among4
for up to months4
and perivascular lymphoplasmocytic infiltrates4
method is subjective due4
the detection of antibodies4
survival rate of neutrophils4
differences in cytokine patterns4
history and interpretation of4
and changes in the4
coronaviruses in blood samples4
differentiation into plasma cells4
standard for the diagnosis4
ste longitudinal systolic strain4
infectious peritonitis after long4
based upon isolates from4
et al in press4
that may cause the4
the vhs and ctr4
were subjected to a4
swine serum in tbs4
of the pulmonic valve4
feline macrophages by monoclonal4
diagnosis of naturally occurring4
progressive interstitial lung disease4
to correlate with the4
dogs in bcs of4
was first described in4
detecting s gene mutations4
infectious peritonitis virus type4
care must be taken4
for the reported sample4
performances of different diagnostic4
be performed in all4
and bronchoalveolar lavage fluid4
presented to the clinic4
in young dogs but4
of hcm in the4
for cd and c4
kg orally every hours4
be involved in the4
is subjective due to4
peritonitis infecciosa del gato4
use of recombinant feline4
acid detection in effusions4
peritonitis using the likelihood4
in cats with the4
with the presence of4
with a titre of4
or exposed to feline4
been shown to have4
murmour was detected in4
cats with signs of4
rfeifn at mu kg4
feline coronavirus antibody and4
the prevalence of fip4
based on results of4
study was therefore to4
as feline infectious peritonitis4
of the control cats4
the retention times of4
coronavirus infection in cats4
amounts of viral antigen4
lymphoma were tested for4
s gene mutations were4
cats in the vaccine4
and development of viremia4
a method that is4
for analysis by rt4
major and minor cross4
fipvs and what they4
be used as a4
sequences encoding for nonstructural4
the th mouse passage4
canine idiopathic pulmonary fibrosis4
crp are associated with4
reverse transcriptase pcr persistence4
in to of cases4
that the incidence of4
other type of feline4
is thought to be4
ii feline coronavirus infections4
of experimentally infected cats4
of life of cats4
american staffordshire terrier and4
before and after surgery4
pathogenesis of feline coronavirus4
the cattery cats and4
in monocytes macrophages and4
strain feline coronaviruses with4
tested positive for type4
on histopathologic examination of4
should be taken to4
may contribute to increased4
has been shown in4
in naturally and experimentally4
used to detect fcov4
reported a sensitivity of4
and physical examination findings4
antibody and nucleic acid4
and fecal shedding from4
the time of the4
were observed in the4
and after being placed4
treatment of feline infectious4
the putative fusion peptide4
for a cat to4
live fipv vaccine under4
for a few days4
and serum crp concentrations4
feline coronavirus persistence in4
used to detect the4
long axis and the4
cats with renal disease4
same animal and even4
in a population of4
to feline enteric coronavirus4
the cd r antigen4
discrepancies between feline coronavirus4
of the coronavirus genome4
clinical neurologic feline infectious4
in the degree of4
of reference range for4
viral antigen in the4
due to feline infectious4
cats against feline infectious4
an important part of4
compared to those obtained4
ml of growth medium4
peritonitis virus infection of4
were positive for fcov4
cd and cd t4
felv fiv status resulting4
role of the feline4
their felv fiv status4
the prognosis for cats4
vegf and cd c4
image quality scores were4
concordance was found between4
from workshops of the4
in cats is mg4
tissue samples were fixed4
urinalysis and abdominal ultrasound4
was used to assess4
with small deletions in4
whether there was a4
pancreatitis in a cat4
in the feces of4
the survival time and4
with the outcome of4
in diameter of the4
protein cleavage site and4
in cats from cyprus4
a high degree of4
accessory and structural genes4
in serum and csf4
diagnostic tests for feline4
one cat was positive4
linked to the development4
a clinical suspicion of4
exposure to fip virus4
are reported to be4
no significant differences between4
and presence of lymph4
be an indicator of4
week compared to week4
is a common cause4
with high antibody titers4
in most cases of4
protocol was based on4
vaccinated with the inactivated4
the siemens dca vantage4
our hypothesis was that4
bronchoalveolar lavage fluid analysis4
none related to this4
kg min in the4
relative copy numbers in4
the saa p protocol4
nested polymerase chain reaction4
virus present in the4
or may not be4
samples were analysed by4
the population of the4
left ventricular internal diameter4
was obtained for each4
cat was positive for4
of dogs were evaluated4
an increase in serum4
mg kg orally every4
control between and days4
but it is important4
management of this disease4
fcov antibodies in the4
feline leukemia virus and4
of small cell lymphoma4
that is commonly used4
act on neutrophils and4
searched for dogs with4
with one or more4
small intestinal bacterial overgrowth4
of each cat and4
of the sequencing step4
between feline coronavirus antibody4
san marco veterinary clinic4
infection with strongyloides spp4
tumors with high c4
of mg kg sid4
histopathologic examination of biopsy4
course of mutian x4
the size of the4
dogs affected by mvd4
of healthy cats and4
online search behaviour of4
on a regular basis4
cytokine patterns in association4
feline infectious peritonitis diagnosis4
common virus infections in4
due to the fact4
is considered the most4
isolated from the feces4
the percentage change in4
the gastrointestinal tract of4
the samples from cats4
body fat analyzer for4
majority of dogs with4
of the acute phase4
terms of the relative4
the role of igg4
portosystemic shunts in cats4
of one of the4
than of the cells4
over time ranging from4
compared to the reference4
in the italian feline4
and of the eia4
body fat percentage which4
ante mortem diagnosis of4
previously been shown to4
has also been described4
the development of a4
alterations of lymphatic tissues4
in challenging clinical cases4
during feline infectious peritonitis4
diagnosis and treatment of4
the feline enteric coronavirus4
cerebrospinal fluid for diagnosis4
in different organs and4
was found between the4
and ifa negative dogs4
with and without ormd4
in the tissue and4
population consisted of cats4
in association with the4
may serve as a4
treatment for sinonasal aspergillosis4
case report describes a4
systemic hypertension in cats4
the canine and feline4
distribution of the virus4
and normal alt levels4
study on the mechanism4
of cats that had4
and expression of the4
as part of the4
not appear to be4
the mesenteric lymph node4
in the cardiac tissue4
in the terminal stages4
by the analysis of4
and the detection of4
healthy cats and from4
results must be interpreted4
to be infected with4
different breeds were included4
dogs and cats and4
of neoplastic intravascular emboli4
both clinically normal and4
vitro plasma protein binding4
mouse monoclonal antibodies in4
clotrimazole cream as the4
with severe pulmonary signs4
methionine codon was identified4
of peripheral blood mononuclear4
leukemia virus and feline4
cardiac long axis and4
statistical analyses were performed4
in blood samples from4
the diagnosis was not4
gene in intestinal tropism4
of fip in cats4
lung of cat n4
the severe acute respiratory4
enrolled in the study4
were collected from fip4
study of cats with4
were divided into groups4
are required to investigate4
been experimentally infected with4
pcr persistence and evolution4
due to the presence4
been reported to cause4
feline coronaviruses with small4
infectious peritonitis in challenging4
were found in the4
there were no dogs4
in whwts with cipf4
igg subclass of mouse4
end of the canine4
was used for the4
has been suggested to4
and high cd c4
in the studied population4
shed in the feces4
quantitative polymerase chain reaction4
demonstration of fcov antigen4
of feline leukemia virus4
in the pelvic limbs4
field strains of fipv4
the underlying disease process4
development of the disease4
the virus in the4
as the percentage change4
the ileum and colon4
virus infection of feline4
the diagnosis of nutritional4
being placed in shelters4
suspected to have fip4
indices of systolic and4
strains of feline coronavirus4
bias of the elfa4
in canine mammary tumors4
evaluated for the presence4
efficacy and safety of4
cats with fip was4
and clinical diagnoses were4
from to weeks of4
it is also possible4
sequences from the same4
such as aspiration pneumonia4
of fcov in the4
the treatment of cats4
pathogenesis of the disease4
kit vegf and cd4
cell differentiation survival factor4
the use of clotrimazole4
none of the cases4
de waal malefyt et4
emphasis on feline enteric4
in naturally occurring feline4
been described in a4
sensitive feline infectious peritonitis4
as an animal model4
the ileal and colonic4
has not been demonstrated4
may be due to4
kipar et al in4
three groups of cats4
time reverse transcriptase polymerase4
infectious peritonitis virus propagated4
exact test was used4
of each sample were4
feline infectious peritonitis clinical4
of the relative density4
prevalence of bartonella spp4
specificity of the sequencing4
the survival rate of4