“Trying to escape microbiology”

“You can take the microbiologist out of the lab, but you can’t take the lab out of the microbiologist”

I was fortunate enough to attend the Olympics in Paris last month, the first time I have ever been to the Olympics. It was a fantastic experience, and we managed to see several events, including football, tennis, athletics, cycling, Rugby 7s and triathlon. Moreover, Paris is my favourite city, so I take every opportunity to visit!

I was hoping to forget all about all things microbiological for a month, and to a large extent this happened, until I was watching the triathletes swimming in the Seine!

You are probably aware of the story, but it was a big thing, and something of a propaganda stunt, allowing the Olympic athletes to swim in the River Seine, and the French Government invested heavily in cleaning up the Seine in order to facilitate this. 

In the end it was touch and go. Heavy rain before the Olympics put the E.coli counts up in the river, and at least one of the training sessions and the men’s individual event had to be postponed due to levels exceeding the acceptable limits.

A few athletes got sick after swimming in the Seine but of course it was virtually impossible to prove that the river swimming caused the illnesses.

Which got me thinking. “What are the acceptable faecal contamination limits for swimming in rivers, and is the risk any different for elite athletes in the Olympics?

There are safety standards set by World Triathlon, which indicate that colony-forming units (CFU) of E. coli per 100 milliliters of water should not exceed 1,000 and enterococci levels should be below 400 CFU/100ml. As one can see from this report, levels were acceptable on the day of the race, but not on several other days.

Of course, the cut-offs for E. coli and enterococci are completely arbitrary… The higher the counts, the higher the level of faecal contamination, and thus the higher the risk. E. coli and enterococci are of course only indicators, as most E. coli and enterococci do not cause gastrointestinal illness. There are a whole range of infections that one can acquire by swimming in faecally contaminated river water, including bacteria, viruses, & spirochaetes. Gastroenteritis is likely the highest risk but ear infections and skin infections can also occur.

There are several other factors that may affect the overall risk. The risk will depend on the range of gastrointestinal pathogens present in the water. I.e. swimming in a river in India might carry a different risk to swimming in a river in Paris even if the E. coli levels are equivalent. The amount of water ingested will also be a factor. I imagine an elite athlete going hell for leather in the Olympic triathlon will be intaking a lot more water whilst swimming than if President Macron goes for a leisurely dip in the Seine, if he ever does. The exposure time will also be a factor. The athletes competing in the 10km distance swimming event will have a lot more cumulative exposure than the triathletes swimming 1500m. Finally, the “host” needs to be taken into account. The cohort swimming in the Olympics will be overwhelmingly young, fit and immunocompetent thus potentially at less risk than the general population.

So clearly it is not as simple as just saying >1000 E. coli per 100ml of water is unsafe and less than that is safe. It is far more nuanced than that.

For elite athletes, whose livelihoods depend on competing in such events, they really have little choice in the matter. For myself however, who is definitely not an elite athlete, I like looking at the Seine, and it certainly appears cleaner than in years gone by, but I will pass on the swimming just for now.

Michael

 

 

 

“A Smorgasbord of Microbiology”

I was fortunate enough to have attended the ECCMID conference in Barcelona a couple of weeks ago, the so-called “Glastonbury” of microbiology conferences. (it is just the drugs that are different…). In general, the conference venue wasn’t great, but the industry exhibition was very impressive, a massive well-lit hall with a true smorgasbord of microbiology tests & platforms available. There were literally hundreds of stands offering a vast array of products. Some of the stands were very flashy affairs, demonstrating fully functioning microbiology platforms. Most importantly, some were even offering free coffee!, although we all know there is no such thing as a “free lunch”. Microbiology is big business now. It can’t have been cheap to hire the floor space at ECCMID, so it must be worth their while.

Healthcare in general is becoming ever more expensive to fund. There are good reasons for this. There is so much more that we can do now than even a generation ago. Stem cell transplants, CAR-T therapy, new anti-cancer drugs, minimally invasive cardiac procedures (e.g. TAVI) to name but a few. In addition, we have a lot more elderly people. Good healthcare and its associated cost will keep a patient alive, who will then inevitably present later in life with further health issues to manage. Spending on healthcare undoubtedly improves life expectancy, but there is a ceiling on life expectancy and there is a law of diminishing returns which eventually kicks in…

With regards to microbiology, there is no difference really. There are so many more things we can offer in a microbiology lab which we could not offer even 20 years ago. Multi-plex & rapid turnaround PCRs, 16s RNA sequencing, metagenomics are a few examples. There are more antibiotics to perform susceptibilities on, and we can now perform both phenotypic and genotypic susceptibility testing. There are a lot more infectious conditions we can now effectively diagnose, usually with PCR based methods. We are also required to spend a lot more money on good quality assurance frameworks, and rightly so, it’s critically important! The landscape has changed out of all recognition in the microbiology lab. A generation ago, it was mainly culture-based bacteriology. Times have changed

All of this means that diagnostic stewardship plays an increasingly important role in the microbiology laboratory, if we are to have any hope of limiting costs whilst providing good value to the clinicians and patients. What tests and platforms should we have in the laboratory, and which patients should we perform these tests on? Personally, I think diagnostic stewardship should be a key component and focus of the jobs of both clinical microbiologists and laboratory managers alike.

“Diagnostic Stewardship is a never-ending process…”

When wandering around the industry exhibition hall, it is easy to get caught up in the euphoria and hype; “I’ll have one of those, and I’ll take that as well”, but there is now an almost infinite array of things that a microbiology lab can have… The key is to listen to what the industry reps have to offer, and then work out what is going to give most value to your particular patient cohort. Will that 24-plex respiratory PCR improve patient management over and above the incumbent 16-plex? Will this assay which gives me susceptibility results from positive blood cultures in 2 hours instead of 6 hours decrease patient mortality? 

Diagnostic stewardship is a fascinating area. Industry presents us with all these options. It takes an effective team working together in the lab to make the right decisions.

Michael

“A Question of Significance”

We may not always realise it, but reading and reporting bacterial cultures often involves several decisions, which are often performed sub-consciously. What do we work up on the agar plates? What do we report? How do we report it?  Do we perform and report susceptibilities? Should we add a comment to the report? All these decisions influence how the result is perceived and acted upon by clinicians. Don’t underestimate the influence that the microbiology report can have on how the patient is subsequently managed.

For example, let’s say we receive 5 theatre samples from a patient undergoing a routine prosthetic joint revision, and 1 of the 5 samples has a light growth of Staphylococcus epidermidis. If we report this out with antibiotic susceptibilities, and without a qualifying comment, there is a decent chance that the orthopaedic surgeon will act on this result and the patient may well end up on several weeks of antibiotics. On the other hand, if we suppress the susceptibilities, and add a comment stating. “This result is of doubtful significance. Clinical correlation is required. Antibiotic susceptibilities are available on request.”, then it is very likely that the surgeon will simply note the result and observe the patient.

On the other hand, if we isolated a Cutibacterium acnes from a shoulder aspirate in a patient with a history of rotator cuff repair, then it is likely that this isolate is significant and we should convey the result as such, along with antimicrobial susceptibilities.

Best of all in these cases of course is to liaise directly with the requestor/clinician/surgeon, so that further clinical details can be obtained, the likely significance can be better ascertained, and a subsequent management plan developed. However, this is not always possible, nor practical for every single patient.

Whilst I always encourage pragmatic reporting, one needs to be aware of the potential consequences of reporting something as a likely contaminant. I.e. What if this organism is genuinely causing infection? What are the likely consequences for the patient if it has not been reported as such? Can we obtain further samples for culture to confirm or negate the initial result? With sterile site samples & blood cultures, obviously the stakes are higher than with a simple wound swab, but the same principles apply for both scenarios.

Over-reporting of organisms on agar plates is often driven by inexperience or fear. I have seen it many times in my career. Scientists and clinical microbiologists alike are responsible for ensuring that over-reporting of results is minimised. This is very much a team game. In particular, colonies thought to represent plate contamination should hardly ever make it on to the laboratory report. Along the same lines, when an obvious pathogen, e.g. Staphylococcus aureus is found on a mixed plate, to what extent should the other organisms be worked up and reported. If a plate is clearly growing a mixture of enteric organisms, you need a very good reason not to report it as mixed enteric flora, and leave it at that.

The “easy way out” for the microbiology scientist and the clinical microbiologist is to report everything that is found on the plate along with antimicrobial susceptibilities, and then let the clinician make head or tail of it. However, this is dumbed down microbiology and often leads to sub-optimal management of the patient.

Michael