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While completely expected given the steady march of New World screwworm (NWS) through Central America and Mexico over the last several years, this horrific parasite finally crossed the US border back into Texas in the last week, and has thus far been found in several beef calves, a goat and one dog from New Mexico. There’s an overview of NWS for companion animal veterinarians recently published in Clinician’s Brief, or check out our previous post NWS: Primer for Canadian Veterinarians for the basics on this nasty bug. This post is about what drugs we have available to help with prevention and treatment of NWS. Remember that the core component of treatment is removal of the maggots as quickly as possible (and ensuring that they do not reach the ground if they are removed or drop out of a wound), but antiparasitic drugs can be helpful as well, especially for the larvae that may be missed or hard to reach, and they can also help prevent infestation before the damage is done.

Compared to other emerging/re-emerging diseases, we actually have quite few options for treating NWS. Data supporting different drugs is variable, and come from a combination of field studies and basic drug information. In the US, the FDA has given conditional approval or Emergency Use Authorization (EUA) to quite a few products for use against NWS in various species. Beyond that, there are also some other products that should work… lack of conditional authorization or EUA in these cases may be more a reflection of some companies not bothering to pursue the process, rather than the product not being efficacious against this parasite.

Among the effective products for dogs and cats, the main drug class is the isoxazolines. This includes lotilaner, afoxalaner, fluralaner and sarolaner. This class has proven efficacy against NWS, and some products now have approval in the US (more on that below).  Lotilaner’s approval is probably based largely on one small study that showed 100% efficacy (i.e. all larvae died) within 24 hours of a single dose in naturally infested dogs after a single dose (Lopes do Vale et al. 2023). Similarly, afoxolaner (Cutolo et al. 2021) and sarolaner (Oliviera et al. 2019) have shown 100% efficacy in their own small field studies.

Here is a list of some of the products that can potentially be used against NWS in dogs and cats, as well as their current approval / authorization status in the US (if applicable):

Conditional FDA Approval for treatment

  • Credelio Quattro CA-1 (lotilaner, moxidectin, praziquantel): dogs

Emergency Use Authorization for treatment

  • Credelio (lotilaner): dogs and cats
  • NexGard (afoxolaner): dogs
  • NexGard COMBO (esafoxolaner, eprinomectin, praziquantel): cats

Other

  • Nitenpyram also had 100% efficacy within 24 hours of a standard dose in a small study of naturally infested dogs (Correia et al. 2010).
  • Spinosad might be useful, but might be less effective, based on one small study that reported 80% efficacy in treating dogs (Oliveira et al. 2018). I’m wary of comparing all these studies since they are all quite small and heterogenous, but at the same time I wouldn’t reach for spinosad first if there’s no advantage to this product over other available options that might be more effective.
  • Bravecto (fluralaner) has Conditional Approval in the US for prevention and treatment of NWS in cattle, but it’s reasonable to assume it would be similarly effective in dogs and cats, in which it’s used at a similar dosage.

Macrocyclic lactones are another class of antiparasitic drugs used as preventatives in dogs and cats. Examples include doramectin, which has conditional approval in the US for prevention and treatment of NWS in cattle, and ivermectin which has EUA for prevention in cattle. It is critical to note that the doses of these drugs used for heartworm prevention in dogs and cats are very low (e.g.4-6 ug/kg) compared to what is used for prevention and treatment of NWS in cattle (200 ug/kg). So while ivermectin, moxidectin, selamectin and milbemycin might be useful at high doses, we cannot assume that dogs/cats getting products like Heartgard, Inteceptor, Sentinel, Milbemax, Proheart and Advantage Multi for routine parasite prevention have any protection against NWS.

Imidacloprid, which is found in products including Advantage II, Advantage Multi, Seresto collars and K9 Advantix II, is also unlikely to have any significant effect on NWS based on its mechanism of action and the low drug levels found in tissue (where the maggots are found) versus in the skin (where this drug is most effective).

None of these products have approval for prevention of NWS in dogs and cats. That’s likely more of a labelling/regulatory issue rather than a true issue with efficacy. Treatment data are simply easier to get: You find some infested animals, treat them, and see what happens. Demonstrating a preventative effect is tougher, especially in the field: You need to put a bunch of animals on the preventive, and then compare the infestation rate in those animals compared to untreated control animals. For a relatively rare disease (at least in this part of the world), you’d need a massive number of dogs or cats to show a preventative effect. Alternatively, an experimental model could be used whereby animals are given preventives or placebo and then deliberately exposed to the NWS flies, but a study like that is a lot more work, a lot more money, and there’s far less appetite for unnecessary use of animal infection models (especially for a nasty parasite like this). Given what we know about the parasite, the drugs and the disease, I think it’s fair to assume that a drug that works for treatment will be useful for prevention. Although I’d never guarantee complete protection, I’d be quite confident in this group of drugs.

The bad news for the southern US is that NWS has returned and will probably be around for a while, as eradication efforts will take time.

The good news is that, unlike for many other emerging or re-emerging diseases, we have effective treatments already available.

We don’t have any approved products in Canada for treatment or prevention of NWS, and I suspect there won’t be much push from drug companies to get any such approval or authorization, since there’s no threat of NWS becoming an endemic issue here. However, we can approach the management of travelling or imported infected dogs in the same way as it’s done in other countries. The treatments in Canada would be extra-label, but that is not uncommon for many conditions we treat, especially when they are rare in Canada.

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As for a lot (or most) conditions we treat with antimicrobials in dogs and cats, data on how best to use antimicrobials before, during and after dental procedures are sparse. We know that antimicrobials are used a lot for canine and feline dental procedures (Weese et al. 2023), and that a large percentage of said use is probably unnecessary. The same is true in human dentistry; even though they have more data and more guidelines, they still struggle with overuse and poor compliance with best practices.

Part of guideline development is assessing the available evidence. Even when we know evidence is lacking, we still want to assess the issue carefully to makes sure there isn’t more evidence than we thought, and to critically assess what little data may be present to help highlight knowledge gaps.

We recently completed a systematic review of infectious complications of dental procedures in dogs and cats, and the impact of antimicrobial prophylaxis (Weese et al. 2026). Specifically, we addressed a series of questions about use of antimicrobials for routine dental procedures, looking at both peri-procedural (i.e. shortly before and up to 24 hours after the procedure) and post-procedural (i.e. more than 24h after the procedure) antimicrobial administration.

  • Unsurprisingly, we found that data were really limited. That’s important itself.  It’s a gap that needs to be filled.
  • We also found that studies rarely looked at (and were rarely well designed to look at) the key outcomes we care about, i.e. clinical disease. We settled on looking at sepsis, infective endocarditis, local tissue infection and adverse events as the critical outcomes.
  • After some debate, we also included bacteremia (bacteria in the bloodstream) as an outcome of interest, even though it’s not a clinical outcome. Bacteremia is a state that may or may not be associated with disease. People and animals are regularly bacteremic and typically have no consequences from it at all. However, bacteremia can progress to infection in rare circumstances. We wouldn’t normally use a non-clinical outcome like that (especially one that is as common as bacteremia), but most of the comparative studies in dogs and cats focused on bacteremia. So we included it, recognizing the limitations.

The systematic review highlighted the commonness of bacteremia associated with dental procedures, as shown in the figure below of the meta-analysis. The proportion column is the prevalence of bacteremia associated with dental procedures in each study, and the pooled prevalence across studies was 47%.  

These studies didn’t report clinical consequences of bacteremia, but when you consider how many dogs and cats undergo dental procedures, the really high bacteremia rates and the really low apparent incidence of dogs and cats getting sick after their procedures, you can understand how bacteremia (seemingly not a big deal) is not a good proxy for clinical disease (which is a big deal).

To investigate this further, we asked whether dental-associated bacteremia is associated with sepsis, endocarditis or other infectious consequences. Only two studies looked at this. Both were small (total of 22 dogs with bacteremia and 11 without) and no infectious consequences or disease were noted in these animals. The data were so limited we couldn’t evaluate them further or draw any conclusions.

We then asked “In dogs and cats undergoing dental procedures, does peri-­procedural administration of antimicrobials reduce the incidence of endocarditis, sepsis, bacteremia or other infectious complications?” But no studies looked at these clinical outcomes. Only two small studies looked at the effects on the incidence of bacteremia, and the meta-analysis (see below) didn’t suggest there was any beneficial effect. The certainty of evidence was really low of course, based on a variety of factors.

That doesn’t mean we can say antimicrobials for dental procedures don’t have any effect, it just means we have nothing suggesting they do. If we look at human dentistry where there are stronger data, antimicrobials are not indicated for these procedures, apart from in certain high risk patients. Our lack of identified effect has to be tempered because the data are weak, but there’s also nothing suggesting antimicrobials are needed (or useful) for routine veterinary dental procedures in most patients.

If there’s no evidence that peri-procedural antimicrobials are useful, there’s even less reason to think that post-procedural antimicrobials are useful, yet this is commonly done in veterinary and human dentistry. We aimed to address the question “In dogs and cats undergoing dental procedures, does post-­procedural administration of antimicrobials reduce the incidence of endocarditis, sepsis, bacteraemia or other infectious complications?” There were no data for this at all. If we look at data and guidelines from human dentistry, routine post-procedural antimicrobials are not typically recommended, or useful.

Did this review actually tell us anything? Yes and no. I think we ended up with the conclusions we were expecting, i.e. bacteremia is commonly associated with dental procedures, there’s no evidence that antimicrobials are useful for routine dental procedures, and the data are really limited.

The fact that we have no supporting evidence for routine use of antimicorbials for dental procedures was an important finding in this case. When we have an intervention (i.e. antimicrobial use) that has potential harms (e.g. cost, adverse events like diarrhea, selection for antimicrobial resistance, administration challenges, pain from administering a pill to an animal with a sore mouth), the default ought to be not to use it unless we have compelling data or a plausible reason to think that the benefits outweigh the harms. For the routine veterinary dental procedures, we have no such data or reason to justify routine antimicrobial use.

Google’s parent company Alphabet has attracted some attention recently base on its request to release up to 32 million mosquitoes in Florida and California. No, it’s not part of a master plan to annoy people or spread disease. Believe it or not, it’s actually an effective method to reduce mosquitoes and the risk of mosquito borne disease.

The reason this seemingly counterintuitive action works comes down to the biology of the relationship between mosquitoes and a bacterium called Wolbachia, which infects many types of insects and parasites. In veterinary medicine, its most significant role is in heartworm disease in dogs, in which Wolbachia are beneficial to the heartworms themselves, so part of the treatment for heartworm is using antibiotics to kill the Wolbachia.

But in mosquitoes, Wolbachia are harmful, not helpful, so we can use this to our advantage. The plan is to release male Aedes aegypti mosquitoes that are infected with Wolbachia. Remember that male mosquitoes don’t bite, so since they don’t feed on blood they don’t spread disease, but they are important for making future generations of mosquitoes.

  • If an infected male mosquito mates with an uninfected female, no viable mosquito larvae are produced, leading to fewer mosquitoes overall.
  • If an infected male mosquito mates with an infected female, viable offspring are produced, but they are also infected with Wolbachia. This is still helpful though, because infected females have shorter lifespans, and the Wolbachia infection also reduces the survival and transmission of various important pathogens in the females, including dengue virus, zika virus, chikungunya virus and yellow fever virus.  

This is in fact a well proven approach to mosquito control. It’s similar to the release of sterile male flies for eradication of New World screwworm, which is being ramped up even more since the first two cases of the current outbreak were detected in Texas earlier this week. (Check out our previous post on NWS for Canadian veterinarians, and the CFIA announcement on new control measures at the Canadian border.)

This is one of those plans that at first glance may make some people wonder what’s going on. It feeds the conspiracy theory crowd that doesn’t like when anyone does anything, but it’s actually a safe and proven process. Mosquitoes have been called the world’s deadliest animal for good reason, because mosquito borne diseases are leading killers internationally. Using biology to counter biology is both a crude and elegant way to address this problem.

Mosquito image source: https://en.wikipedia.org/wiki/File:Aedes_aegypti.jpg

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I wasn’t very quick to write about this because while some incidents of contamination of raw pet food prompt recalls, such contamination is a largely expected event that occurs every day under the radar.

This was also another example of a company ignoring an FDA request to recall raw pet foods in response to contamination, but that too is unfortunately a well known phenomenon when it comes to raw pet food companies.

Listeria contamination adds another dimension, though. Listeria is notorious for contaminating production facilities, particularly those that have suboptimal cleaning, disinfection and maintenance. This can result in widespread and prolonged contamination, with corresponding disease risks. The large number of diets (and over 180 lots) involved in this recall shows the potential scope of Listeria contamination. The company ignoring the problem for some time also likely contributed to unnecessary infections (both detected and undetected).

This recall finally happened months after the US FDA issued a recall request in January 23, 2026 following an owner complaint about their sick dog, and after more reports of dogs on the diets getting sick. The initial recall request was for just 8 lots of various diets, all of which had tested positive for Listeria and other bugs. It’s hard to say how many animals got sick as a result of this incident; Listeria could easily be missed in a dog or cat since it’s not something for which veterinarians typically test.

The company finally responded with a recall on May 22, 2026. The recall affects Raaw Energy diets produced between July 17, 2025 and Dec 23, 2025, as well as “Beef and Turkey Medley” lots produced on March 31, 2026. The notice also states “Some products produced during this timeframe were not tested, and bacterial presence was identified during the same period. As a result, products manufactured within these dates could possibly be affected.” Based on this, combination with the wide date range, I would assume that any diet from this company could be involved at this point. Lack of a positive test for a particular diet doesn’t mean much unless you know how much testing was done.

Ignoring FDA recall requests is an unfortunate pattern with some raw pet food companies. It took months for this company to take action, creating more disease risk for animals and people. I can’t understand why companies are allowed to do this, nor why consumers would continue to purchase from a company that ignores an FDA recall request. If nothing else, you’d think the company would be worried about legal liability if there are further illnesses (especially in people handling the food, or those living with / looking after the dogs), but apparently the short term benefit of ignoring the FDA and continuing to sell contaminated food took precedent.

I’m not going to get into the raw pet food debate (again) here. There’s lots of information in our blog archives, and more information about risk reduction with regard to raw diets can be found on the Worms & Germs Resources – Pets page. Regardless of differences in opinion about the pros and cons of raw diets, I hope we can at least agree on not feeding pets food from companies that ignore food safety problems and contribute to unnecessary disease spread.

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I’ve seen quite a bit of “can your dog or cat get hantavirus?” discussion in media lately, in follow up to the recent cluster of human hantavirus cases associated with a South Atlantic cruise ship. Fortunately, unlike past articles about many other emerging infectious diseases, these have mainly been pretty low key. They’ve highlighted the minimal concern about dogs and cats getting infected and even lower concern that they could infect someone else. Yay.

It is nonetheless important to note is that research on hantavirus in dogs and cats is very limited, so we need to consider “absence of evidence” vs “evidence of absence”. We don’t even know all we need to know about this hantavirus strain (Andes virus) in people; the unique nature of the cruise ship cluster shows this. Animals are much lower down the research priority pecking order.

A few studies have looked at antibodies against hantaviruses in healthy dogs and cats. Finding antibodies means the animal was likely infected at some point and fought off the infection. It doesn’t tell us whether or not they got sick, or whether they could have spread it, but it gives us a basic indication of susceptibility.

These studies tell that a small but appreciable percentage of dogs and cats in areas where hantaviruses are present have evidence of past infection. That’s not overly surprising. They don’t tell us if they got sick or not. If illness caused by hantavirus was really common, we might figure it out based on the clinical cases popping up, but we don’t do a good job identifying rare, sporadic problems, especially in pets, because they’re not routinely tested. I’ve dealt with lots of cases of severe respiratory disease in dogs and cats, and have never tested for hantavirus (maybe we should in some regions, but finding a lab that offers a PCR test for the virus would be the first step). So I’d be wary of dismissing the possibility too quickly, but at the same time it’s not something I’m worried about.

The risk to people posed by infected animals is presumably even lower. We know that people are susceptible to hantaviruses and can get severe disease. Infected people should be more likely to transmit hantaviruses, yet that seems to be really rare, and only a concern with one type of hantavirus (the Andes virus, which was identified in the cruise ship cluster). If dogs and cats are less susceptible to infection in the first place, they likely pose even less risk of transmitting the virus.

Furthermore, we need to remember that not all hantaviruses are the same. There are actually numerous hantaviruses, each with different reservoir hosts and potential issues. We don’t have good data for all the different combinations of hantavirus types and animal species.

While lack of evidence of a problem doesn’t mean there’s no potential problem, it’s encouraging. We have known about hantaviruses for years, and domestic animals have had lots of exposure. Dogs and cats may be at higher risk of exposure than people because they are more likely to catch reservoir hosts (rodents) or root around areas contaminated with rodent urine and feces. Since we’re not seeing suspicious hantavirus cases in dogs and cats, that’s a good sign that the risks are at least low.

BUT we can’t ignore the potential risk altogether. A little common sense is useful to mitigate risks, especially when we don’t know what they are or if they exist. A lot of it is just applying the prevention messaging that is going out to people to other animals.

  • Limit contact with rodents. That is easier said than done for free-roaming dogs and cats, but efforts to keep animals under control and reduce rodent exposure are useful for a bunch of reasons.
  • Reduce rodent access and infestations in households.
  • Take care in areas potentially contaminated with rodent feces and urine. If you’re cleaning out your contaminated shed, maximize ventilation, wear gloves, mask, and eye protection, and wet down surfaces before disturbing them (e.g. sweeping). Also don’t let your dog “help” by shoving his nose in every contaminated corner (or as the case would be with my dog Ozzie, eating everything he can find).

Those are the main things I’d recommend for dogs and cats in areas where hantaviruses are present. Realistically, I’d say the same thing for any other area too, since it’s possible there is unknown hantavirus activity, and hantavirus isn’t the only infectious disease concern when it comes to rodent contact.

Don’t panic over hantavirus, especially when it comes to pets. However, we shouldn’t ignore the potential for animal and interspecies concerns. More surveillance would help determine what the issues really are.

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I got a lot of media questions about hantavirus after the recent cluster of human cases was identified associated with a cruise ship, but those questions were primarily focused on basic facts about virus itself and its general epidemiology. As things have dragged on, there are now more questions about hantavirus and companion animals – not because there are any major issues with pets and this virus, but more likely just because people are getting bored with the usual talking points and are looking for other content.

That said, there are some interesting aspects to consider when it comes to hantavirus and dogs and cats. Pets can be exposed to hantavirus just like people, through contact with reservoir species (i.e. rodents), or their feces, urine or saliva. Cats and dogs are technically at higher risk of exposure in many ways, since they are more likely to have close contact with rodents and to be sniffing around contaminated areas.

I want to start with the key point that the issues with hantavirus in pets are near negligible. I’m going to talk about some areas we should think about with emerging or unusual disease events out of an abundance of caution, not because there’s a major concern with this specific event. So please don’t freak out. Finding that sweet spot between awareness and panic is tough with infectious diseases.

This post will focus on issues to consider specific to the cruise ship cluster. I’ll try to cover some of the more general considerations with hantavirus and pets in another post.

Key point: Despite evidence of human-to-human transmission of this particular hantavirus strain (Andes virus) on the ship, such transmission is still rare. If human-to-human transmission is rare, human-to-pet transmission should be at least as rare, if not even rarer.

Issues with pets and emerging diseases in general revolve around three main concerns:

  1. Pets getting sick (concern for pet health and potential for them to be sources of infection)
  2. Pets getting infected but not sick (no concern for pet health, but bigger to other animals and people to have infectious but apparently healthy animals around us)
  3. Pets acting as vectors of a pathogen whereby they are not infected but can move the virus from place to place (e.g. virus contamination of their haircoats)

We don’t know that any of these are an issue, and they are probably of no concern with this cluster. Infections in dogs and cats are already very rare, and even if infected, the transmission risk from a pet would be very low. But this is also an opportunity to take some basic and practical prevention measures when the risk isn’t well known.

I haven’t seen any reports of dogs being on the ship (e.g. service animals). That removes the highest risk situation with regard to transmission. That leaves us with pets owned by people who have left the ship. Those who have been released from the cruise ship are being monitored, and in some situations tested. Different countries are taking different approaches, but it seems like voluntary quarantine is being used in many places. That focuses primarily on keeping potentially exposed people away from other people. The question I always have with household quarantine is “what about the pets?” This question seems pretty simple, and has come up in the context of various diseases, but rarely do we get an answer.

  • If someone is quarantining in a household, we need to know if they have pets, and if there is a risk to/from the pet for the disease in question. If there is, or if we can’t say there’s no risk, we should treat the animal like a person, i.e. try to keep the quarantined person away from the pet as well. That helps ensure they don’t infect or contaminate the animal, both for the animal’s health and to avoid the risk the pet might then pose to other animals or people.

With other infectious diseases (not likely applicable here), there can also be concerns about the animal acting as a mechanical vector that can lead to indirect transmission, similar to a contaminated surface or object. As I’m writing this, Alice (my cat) is perched next to me. If I have a respiratory virus and touch my face, and then her, I may contaminate her haircoat. If she then visits someone else in the house they pet her a short time later, that could transfer virus to them, even though Alice wasn’t infected. The worst case scenario is I contaminate or infect Alice, and then she goes outside and infects another animal. Then maybe I’ve released the virus into the broader community, or the wildlife population. This was something we were trying to get across when voluntary isolation was used when SARS-CoV-1 emerged in the early 2000s, and then again with SARS-CoV-2 during the COVID-19 pandemic (rarely with any success).

Again, the issues with this hantavirus cluster specifically are very limited and there’s probably no concern:

  • The odds of a person that is quarantining being infected are really low.
  • The odds of an infected person infecting an animal are even lower.
  • The odds of a person being infected, infecting their animal and that animal getting sick or transmitting the virus to someone else approach zero.

So, why are we even talking about it? Good question. We probably know enough about Andes virus to just say “don’t worry.” However, our knowledge of the potential role of pets in a lot of diseases is pretty low, and we can take simple steps to reduce that risk.

My emphasis here is we should default to assuming there could be cross-species transmission issues and apply basic control measures accordingly, unless/until we determine that there’s no need, rather than waiting until we see a problem and then reacting. With Andes virus, a rapid risk assessment could be done to determine the likely risk and the relative certainty of risk, to determine whether or not it is necessary to tell people to isolate from animals too. Despite all our past experiences and recognition of the scope of susceptible species for many emerging diseases, we are still reactionary when it comes to risks to and from animals.

  • Do I want people to worry about their pets if they’ve been exposed? No.
  • Do I want exposed persons to isolate from their pets? Maybe. If they are isolating from people, it makes sense to isolate from their pets. However, if that’s not practical or if the pet is the person’s key emotional support through quarantine, I’d have them quarantine together.
  • Do I want people to fear animals that might have been in contact with an exposed person? No. We’ve seen over-reactions like this in the past.

The issues with hantavirus and most pets are near negligible, but it’s another reminder that the difference between “humans” and “animals” is in our brains. To a virus, we are all just animals of different species, and we all have the potential to be a nice susceptible host.

Carbapenemase-producing Enterobacterales (CPE) is a group of bacteria with resistance to powerful carbapenem antibiotics such as meropenem. They’re also usually resistant to various other antibiotics, which makes them a big concern because treatment options are very limited, and unfortunately the rate of CPE infections in people is increasing rapidly. To treat them, physicians typically need to use one of the limited number of other powerful antibiotics that may still be effective, but the more we have to use these limited drugs, the more resistance to them we’re going get. It’s a cascading problem.

CPE are predominantly an issue in humans, but they can cause infections in animals too, and in a lot of cases the CPE is likely spread from humans to animals. Regardless of the source in each case, the more widely these resistant bacteria are found, the greater the risk they pose to both people and animals.

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The US CDC’s Emerging Infectious Disease journal has posted a podcast on this topic, following up on a recently published study entitled Genetically Similar High-Risk Strains of Carbapenemase-Producing Enterobacterales in Humans and Companion Animals, United States (Xiaoli et al. 2026). Unfortunately, I think we’re going to hear more about CPE in animals in coming years. Information on CPE cases in people in Ontario is available from Public Health Ontario.

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As H5N1 influenza continues to circulate in wild birds, and spillover into a wide range of other birds and mammals, it’s difficult to find the right messaging with regard to the risk of transmission to people.

  • Historically, H5N1 influenza has had a reported mortality rate of 30-50% in people, but it been a lot lower with the strains currently circulating in most parts of the world.
  • Human infections with H5N1 influenza continue to be really rare overall, but they do occur. Generally milder disease doesn’t mean always milder disease, and a small number of fatalities have been reported in the last few years.
  • Spillover of this virus into domestic animals (including poultry, cattle and cats in particular) continues to occur. These spillovers create more risk to people given the closer and more frequent human contact with domestic animals, but surveillance has been limited in household animals such as cats and dogs.

Communicating risks in situations like this is challenging, since we want to raise awareness so people recognize that there is some risk and a need to take basic precautions, but at the same time, we want to make sure there’s no panic and that the risks are dealt with in a reasonable manner. The sweet spot between awareness and paranoia is often tough to find with infectious diseases (as the current cruise ship hantavirus cluster also shows, but that’s another story).

A recent report in CDC’s Morbidity and Mortality Weekly Reports describes a case of suspected cat-to-human transmission of H5N1 influenza in California. It highlights some risks that we’ve been trying to message for a few years now.

  • The good news is the incident didn’t make the person sick (or at least not sick enough that it got reported. The bad news is that there is evidence that tranmission from the cat occurred at all.

The report describes follow-up of people in Los Angeles County who were exposed to cats that got H5N1 influenza from consuming contaminated raw milk or raw diets.

  • There were ultimately nine confirmed feline cases, and ten other suspect cases.
  • 139 people exposed to these cats were monitored for symptoms of flu; of those, 30 developed flu-like illness.
  • 33 people, including 18 of the people who had signs of upper respiratory tract infection, were tested for H5N1 flu by PCR and all were negative, while 36% tested positive for another respiratory virus (mainly human seasonal flu).

PCR testing mostly detects active infection, where the virus is still present. The challenge with this kind of surveillance is that by the time the cats were diagnosed, contacts identified and notified, and testing performed, the virus was likely to be long gone in people (if it was there at all).  Flu infections tend to have a short incubation period (from exposure to onset of illness), and people don’t shed the virus for very long. The median time from exposure to testing in these individuals was 8 days, which is stretching it for flu, no negative results are not surprising, but can’t entirely rule out transmission.

A complementary testing method is looking for antibodies in blood (serology). Antibodies take time to be produced, but they can stay in circulation for a fairly long period of time. So, someone who was infected a few weeks ago would likely be PCR-negative but antibody-positive. The presence of antibodies tells use there was exposure to the virus at some point, but not when. That’s a big limitation of serology in some situations, but in this case where we suspect the risk of exposure to H5N1 flu other than the known contact with the infected cats is very unlikely, finding antibodies in a person is a pretty solid indication that they were infected by the cat.

Twenty-five (25) of the individuals exposed to the infected cats were tested for H5N1 antibodies, and one was positive – a veterinarian, who had no other identified risk of exposure. They didn’t get sick, but they worked on an infected cat without using any respiratory or eye protection (high-risk contact). That makes it a pretty solid presumptive diagnosis of cat-to-human transmission of H5N1 influenza, even though the person was PCR-negative for H5N1 flu when tested 7 days after exposure (so likely missed the viral shedding period).

You might say “they didn’t get sick, so who cares?” At the individual level, that’s fair, but there are broader issues. This case shows that infected cats do pose some degree of risk to people (which we’ve suspected all along). While this person didn’t get sick, the next person might not be so lucky, based on the dose of virus to which they are exposed, their underlying health, and random quirks of disease.

While the H5N1 virus is still not well adapted to people, the more it’s transmitted between mammals, the greater the risk of it adapting to become better able to infect mammals (including people).

We’re also worried about someone with regular human seasonal flu getting exposed to H5N1 flu at the same time. That creates the potential for recombination, whereby the two flu viruses mix together in the same host, potentially creating a new virus strain with the worst parts of both the seasonal flu virus (i.e. easily transmitted between people) and H5N1 flu (a “new” virus to which there is limited individual and population immunity, and potentially could cause more severe illness).  That’s how pandemic viruses emerge. The odds of that happening are low, but the more the viruses mix in different species, the more that risk increases. Here, a reasonable number of people who were exposed to H5N1-infected cats had confirmed seasonal flu infections, so it’s far from a theoretical risk.

Ultimately this report doesn’t really change the current story much, but it’s documentation of something we had assumed would happen. It reinforces the need to take basic infection control precautions around sick cats that have potentially been exposed to H5N1 flu, to take steps to limit exposure of cats to this virus (like keeping them indoors when possible), and to continue surveillance in this and other species.

And as we saw with cat-to-human transmission of SARS-CoV-2 , veterinarians are at the forefront of this risk.

“Doing nothing often leads to the very best of something.” ~Winne the Pooh

I don’t think the beloved wise sage of a bear was thinking about urine when he said that, but we can nonetheless heed the guidance of Winnie the Pooh when it comes to the management of subclinical bacteriuria. Here’s why:

Subclinical bacteriuria (also called asymptomatic bacteriuria in people) is a condition in which bacteria are present in the urine without causing any disease. In the past, this has often been considered something that needs to be treated, but we now know that the bladder isn’t always a sterile environment, and having some bacteria in it isn’t necessarily bad. Bacteria cycle in an out of the bladder, and subclinical bacteriuria is a common (normal) state for some animals (and people). We also now know that it rarely needs to be treated. In humans, the main indications for treatment are pregnancy and treatment prior to undergoing a urological surgical procedure. Unfortunately, it’s often treated unnecessarily (in both people and animals), which can lead to issues with adverse effects of antimicrobials, antimicrobial resistance, unnecessary costs and unnecessary hassles and stress.

When the first edition of the ISCAID antimicrobial use guidelines for urinary tract disease in dogs and cats (2011) was released, many people pushed back at the recommendation to not treat (or even test to look for) subclinical bacteriuria. By the time the second edition of the ISCAID guidelines for diagnosis and management of bacterial urinary tract infections in dogs and cats (2019) was published, there was a lot less resistance to this recommendation, but unnecessary treatment of this condition is still relatively common. As we continue work on the newest update to these guidelines, we hope for even better uptake, but realize that old habits die hard.

Subclinical bacteriuria is still often treated because of habit or fear. We need to focus on a few concepts to move past this out-of-date practice:

  • We treat disease, not culture results.
  • Not all bugs need to die.
  • If a bacterium isn’t bothering my patient, it shouldn’t bother me (with rare exceptions).
  • Doing something isn’t always better than doing nothing (even though we’re hard wired to think we need to do something). Listen to Winnie!

A new study in the Journal of Veterinary Internal Medicine (Le Corre et al, 2026) provides more support for Pooh’s clinical sense. It’s not earth shattering, and it’s not surprising, but it’s a really important part of providing more data help convince clinicians to leave it be.  

The study is entitled Clinical outcomes and association with disease progression and survival of subclinical bacteriuria in cats with chronic kidney disease: a multicenter retrospective study. The researchers looked at 287 cats with chronic kidney disease, which is a population that’s at increased risk for subclinical bacteriuria. All the cats had urine cultures from samples collected by cystocentesis (i.e. using a needle and syringe to inserted directly into the bladder through the body wall to help reduce contamination of the sample), and none had any signs of lower urinary tract disease (e.g. straining to urinate).

  • Bacteria were isolated from the urine of 38% of cats, which is pretty much in line with prior estimates of subclinical bacteriuria in this population. Unsurprisingly, female cats were 5.3 times as likely to have bacteriuria compared to males.
  • Eschericia coli was the most common bacterial isolate, accounting for 68% of positive cultures, followed by Enterococcus (17%), Staphylococcus (5%) and Pseudomonas (5%). Twenty percent (20%) of bacteria were multi-drug resistant (ugh).
  • Eighty-five (85) of the cats with subclinical bacteriuria were treated with antibiotics, of which 41% were treated before antimicrobial susceptibility data were available.

In cats treated with antibiotics, bacteriuria was identified again later on in 62% of them.

  • That’s a key point. It demonstrates that treating the cats didn’t do anything to change their susceptibility to future episodes of bacteriuria, so it’s not surprising it happened again. This highlights the futility of treating this condition. If we eliminate the bacterium in the bladder today, odds are a new one will move in in the near future. The more we treat, the more likely we are to harm the cat (e.g. adverse events from the antimicrobial treatment), and the next time bacteriuria occurs, it may be resistant to our first line drug of choice. If the cat then develops an actual clinical infection that needs antimicrobials, we may have more limited treatment options.

When the researchers looked at 1500 day follow up in these cats, there was no association between subclinical bacteriuria and survival (see graph below). That fits with an earlier study of bacteriuria in senior cats, and with reams of data from human medicine.

Progression of chronic kidney disease was also assessed in 134 cats. There was no difference in percentage of cats that showed progression of disease in the group with subclinical bacteriuria (42%) versus controls (40%). The detection of multiple episodes of subclinical bacteriuria was also not associated with progression of kidney disease.

There was no statistically significant difference between groups in the development of bacterial cystitis, though there was a numerical difference that’s worthy of further investigation That said, an additional question would be whether cats that were treated were more likely to have other complicating factors that were a driver for cystitis. There was also no significant increased risk of pyelonephritis in untreated cats.

All this supports the notion that subclinical bacteriuria is a common and typically benign state. Treatment can sometimes eliminate bacteria, but not always, and when it does, recurrence of bacteriuria is common. It’s possible that treatment would reduce the subsequent risk of bacterial cystitis, but even if there’s a small effect, we need to consider the potential adverse events associated with treatment, especially when treating lots of cats over and over again.

This was the researchers’ conclusion:

…we found no significant association of SBU with survival and disease progression in cats with CKD. Despite antimicrobial treatment of SBU in cats with CKD, urinary sterilization was not achieved in most cases, and progression to bacterial cystitis or pyelonephritis, although infrequent remained possible. Despite the fact that no clear guidelines for the management of SBU in cats with CKD currently exist, our results do not support routine antimicrobial treatment of this condition. Further evidence on the appropriateness of withholding treatment to manage SBU in cats with CKD remain however to be demonstrated before such recommendations can be made.

Image source: https://tommccallum.com/2021/05/21/doing-nothing-often-leads-to-the-very-best-of-something/

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Colorado State University, in partnership with the University of Bristol, is recruiting licensed veterinarians who have encountered at least one case of Feline Infectious Peritonitis (FIP) since 2019 to complete a brief (20 minute) online survey examining clinicians’ experiences and comfort levels with diagnosing FIP and using antiviral therapies for FIP in cats. Please participate if you meet this criterion!

Your participation is voluntary, and your responses will be kept confidential. Insights from this study will help inform the development of future veterinary education resources related to FIP diagnosis and treatment.

IRB#: 7613 (approval date 02/19/2026)