EDF Health

CDC finally describes its derivation of “safe” level in WV spill – but erroneously claims it to be “highly conservative”

Richard Denison, Ph.D., is a Senior Scientist.  Jennifer McPartland, Ph.D., is a Health Scientist.

Slowly but surely, like the movement downstream of the spill’s plume, we are learning more about how government officials derived the 1 ppm “safe” level in the drinking water for the chemical MCHM that was spilled into West Virginia’s Elk River late last week.

A few more slivers of light were cast today onto what has been a remarkably opaque procedure used by CDC and other officials to set the 1 ppm level, which got even more confused with last night’s issuance of a “Water Advisory for Pregnant Women” by the West Virginia State Department of Health. 

The slivers come from a story today in the Charleston Gazette by Ken Ward, Jr. and David Gutman reporting on their conversation with an official from the Centers for Disease Control (CDC), and a media call today with the same official. 

CDC finally gave a fuller description of their methodology, and while it appears to have more closely followed standard practice than the methodology they initially described, many questions remain about the study used as the starting point.  Release of these studies, therefore, is essential.  [UPDATE:  EVENING OF 1/16/14:  Late today, Eastman finally made its studies public:  they are available here.] 

We discuss the details further below.  But first:

CDC’s erroneous claim that its “safe” level is “highly conservative”

CDC’s claim that the 1 ppm level is “highly conservative” is not warranted on scientific grounds.  This claim is based on its use of three 10-fold adjustments, referred to by CDC as “uncertainty factors,” to extrapolate from a dose identified in an animal study to a level in drinking water consumed by people.

  1. An “interspecies extrapolation” uncertainty factor to account for the fact that humans may be much more sensitive to the effects of a chemical exposure than rats.
  2. An “intraspecies extrapolation” uncertainty factor to account for the fact that humans differ in their sensitivity to a chemical exposure (e.g., infants or the elderly vs. healthy adults).
  3. A third uncertainty factor to account for how few data are available on the chemical and hence the likelihood that its health effects that have not been identified may occur at doses much lower than the doses for the health effect that has been studied.

The CDC official referred to these adjustments as “safety factors” – implying they provide for a large margin of safety.  This is FALSE.  These are REALITY FACTORS.

Each of these accounts for known circumstances with regard to the effects of chemical exposures on people in the real world.  There are plenty of examples of chemicals where:

  1. humans are 10x (or more) more sensitive than rats to a chemical effect, and
  2. the most vulnerable/sensitive human is 10x (or more) more sensitive than the least vulnerable/sensitive, and
  3. an effect not considered in a given study occurs at a dose that is 10x (or more) lower than the effect looked at in the study.

Don’t take our word for it, but rather the National Academy of Sciences, in a seminal 2009 report titled Science and Decisions:  Advancing Risk Assessment (p. 132, emphases in original):

Another problem … is that the term uncertainty factors is applied to the adjustments made to calculate the RfD [reference dose, derived from, e.g., a no-effect level] to address species differences, human variability, data gaps, study duration, and other issues. The term engenders misunderstanding: groups unfamiliar with the underlying logic and science of RfD derivation can take it to mean that the factors are simply added on for safety or because of a lack of knowledge or confidence in the process. That may lead some to think that the true behavior of the phenomenon being described may be best reflected in the unadjusted value and that these factors create an RfD that is highly conservative. But the factors are used to adjust for differences in individual human sensitivities, for humans’ generally greater sensitivity than test animals’ on a milligrams-per-kilogram basis, for the fact that chemicals typically induce harm at lower doses with longer exposures, and so on. At times, the factors have been termed safety factors, which is especially problematic given that they cover variability and uncertainty and are not meant as a guarantee of safety.

CDC’s Methodology Revealed

Until yesterday, all indications were that the 1 ppm level was derived from a single oral lethality study in rats that is not publicly available but reported a median lethal dose value (LD50).  Yesterday, CDC referred to “additional animal studies” that were under review.  In today’s Charleston Gazette story and this afternoon’s call, the CDC official indicated for the first time that CDC used a second study – also not publicly available – as the starting point for the calculations.  This second study was stated as identifying a “No Observable Adverse Effects Level (NOAEL)” for MCHM of 100 milligrams per kilogram of body weight per day (mg/kg/day). 

[UPDATE 1/17/14:  This study, finally made available late yesterday, was performed using “pure MCHM” (97.3%) rather than the “crude MCHM” mixture that was the material actually spilled.  This adds some additional uncertainty; if other components besides MCHM present in the crude mixture are more or less toxic than MCHM, the mixture’s toxicity would differ from that found for the pure material.]

Numerous questions about this study remain unanswered that bear on its relevance for the purpose to which it has been put.  Just a couple key ones:

  • What health effect(s) were looked for?  and which ones were not considered?  [UPDATE 1/17/14It appears that the study looked for changes in standard blood chemistry and biochemistry parameters, and included histopathological examination of all major organs to look for abnormalities.] 
  • How long were the animals exposed – a day? a week?  a month?  [UPDATE 1/17/14:  The study report indicates the animals were exposed for 4 weeks.] 

But at least we now know how CDC made the calculation that led to the 1 ppm level:

  1. CDC started with the reported NOAEL of 100 mg/kg/day, and divided it by the three uncertainty factors (10 x 10 x10 = 1000) to arrive at a “reference dose” of 0.1 mg/kg of body weight/day.  This is the amount of the chemical that, under the assumptions made, could be presumed “safe” to ingest.
  2. It then assumed an “average child” weighing 10 kilograms (about 22 pounds) was drinking water at an average rate of 1 liter per day (about 34 ounces).  These average values are typical assumptions for use in risk assessment.
  3. Then CDC multiplied the 0.1 mg/kg of body weight/day by the 10 kg average body weight, resulting in 1.0 mg/day for a child as the amount that could be ingested without seeing an effect, again under the assumptions used.
  4. That 1.0 mg/day was then divided by the average water consumption of 1 liter/day to yield 1.0 mg/liter as the concentration in the water consumed identified by CDC as the “safe” level.
  5. That 1.0 mg/liter is equivalent to 1 ppm.

Welcome to the wild and woolly world of risk assessment, folks.  More to come, we’re sure.

Also posted in Health policy, Regulation / Tagged , | Read 2 Responses

West Virginia issues drinking water advisory for pregnant women in wake of chemical spill

Richard Denison, Ph.D., is a Senior Scientist.

Shortly after 8pm this evening, the West Virginia Department of Health issued a “Water Advisory for Pregnant Women” in connection with last Thursday’s chemical spill.  The news was first reported by Ken Ward, Jr. and David Gutman in the Charleston Gazette.

The Advisory states:

The West Virginia Bureau for Public Health advises, after consultation with the U.S. Centers for Disease Control and Prevention (CDC) this evening, that the CDC recommends—out of an abundance of caution—that pregnant women drink bottled water until there are no longer detectable levels of MCHM in the water distribution system. However, the CDC re-affirmed previous advice that it does not anticipate any adverse health effects from levels less than 1 ppm.

Guidance from the CDC is attached.

Two other documents are available:

It is unclear what prompted tonight’s issuance of the Advisory, which comes six days into the spill.  However, one clue may be in the CDC letter, which states:

Since making the initial calculations, scientists have obtained additional animal studies about MCHM.  These are currently being reviewed.  At this time, the scientists continue to recommend 1 ppm as a protective level to prevent adverse health effects.  However, due to limited availability of data, and out of an abundance of caution, you may wish to consider an alternative drinking water source for pregnant women until the chemical is at non-detectable levels in the water distribution system. (emphasis added)

It appears the new information prompted the CDC recommendation that West Virginia consider advising pregnant women to avoid drinking the water, which raises the question as to whether the new animal studies suggest a potential for developmental toxicity or a related effect.

It should be noted that the answer to the first question in the FAQ document states: “There are no known studies showing harm to the fetus as a result of consuming water with MCHM levels below 1 ppm.”

Clearly something prompted the issuance of the advisory.  I hope we’ll learn more shortly.

Questions have already been raised on this blog about the lack of data on this chemical and the methodology used by government officials to calculate the 1 ppm level.  This new development, however, I believe lends even greater weight to the need for immediate public release of both all available studies and the methodology.

 

Also posted in Health policy, Regulation / Tagged , | Read 1 Response

West Virginia officials trust shaky science in rush to restore water service: One-part-per-million “safe” threshold has questionable basis

Richard Denison, Ph.D., is a Senior Scientist.

[SEE NOTE ADDED 1/15/14 BELOW]

In a press conference today outlining plans to restart the water system serving 300,000 people, West Virginia state officials and executives from the West Virginia American Water utility company stressed that levels of the toxic chemical that contaminated the supply after last week’s spill had reached a “safe” level of one part per million (1 ppm), the threshold agreed upon by state and federal officials on Saturday.

Unfortunately, the science behind this standard remains unclear.  Based on what we do know, there are good reasons to believe that officials are overlooking significant health risks.  Read More »

Also posted in Health policy, Regulation / Tagged , , , , | Read 36 Responses

No disappearing act: Dispersant ingredient lives on months after BP oil disaster

Richard Denison, Ph.D., is a Senior Scientist.

Remember that old naïve saw, “Dilution is the Solution to Pollution”?   When it comes to the dispersants used last year to address the Deepwater Horizon disaster in the Gulf of Mexico, that axiom appears to be the operative mechanism.

Last week, researchers at Woods Hole Oceanographic Institute published data showing that a key component of the Corexit dispersant used by BP to address the oil spill, did not degrade – as had been predicted by just about everybody, including BP, the Coast Guard, the dispersant manufacturer Nalco and EPA.  In fact, it was still detectable when last looked for in September, 5 months after the spill began and at least two months after use of dispersants had ceased. Read More »

Also posted in Health science / Tagged , | Comments are closed

New EPA data: Dispersant likely not increasing acute lethality of oil in BP oil disaster

Richard Denison, Ph.D., is a Senior Scientist.

I had reported in an earlier post – based on data provided to EPA by Nalco, the maker of Corexit® 9500, the main dispersant being used in the Gulf – that the dispersant appeared to increase the acute aquatic toxicity of oil.

At a press conference today, EPA released data from the second round of its own testing on Corexit 9500 (and seven other dispersants), and concluded that the acute toxicity of the dispersant-oil mixture is about the same as the oil by itself.

What explains the discrepancy?  To put it most simply:   It’s not that the dispersant-oil mixture was less toxic in the EPA tests, it’s that the oil EPA used – which is the actual oil that has been leaking into the Gulf – was more toxic than the fuel oil Nalco had used.  Here’s a cartoon illustrating what I’m saying (the arrow shows the biggest change):

So the good news is that the dispersant doesn’t appear to be increasing the acute aquatic toxicity of the oil released into the Gulf.  The bad news is that the oil is pretty toxic, and the dispersant certainly doesn’t help directly with that.  And of course, the bigger questions about longer-term effects of dispersants and dispersed oil are not addressed by the new data.   Read More »

Also posted in Health science / Tagged , | Read 4 Responses

Exceptions swallow the rule: “Rare cases” turn into daily approvals for dispersant use

Richard Denison, Ph.D., is a Senior Scientist.

What the EPA hath sought to take away from BP, the US Coast Guard hath given back.

Remember the May 26 Directive that, well, directed BP to “eliminate the surface application of dispersants” except in “rare cases when there may have to be an exemption” and where BP submits a written request and receives an exemption in writing from the Federal On-Scene Coordinator (FOSC, currently Admiral James Watson of the Coast Guard)?

Naturally, I was curious about the nature and number of such exemptions, given that, as I noted earlier, surface application of dispersants has continued since the May 26 Directive.  After I (and others, I expect) made inquiries a couple of weeks ago to get copies of the written requests from BP and written approvals from the FOSC, the Coast Guard has informed me that it has posted these documents on the Deepwater Horizon response website.

These documents reveal that, as of June 30 (the last day for which a document has been posted as of this writing), more than 40 exemption requests have been submitted – and approved.  These exemptions have allowed surface application of dispersant to occur virtually every day since the Directive was issued.

The documents also hold some other interesting details as to the rationales offered for the exemptions and the nature of the approvals.  Read More »

Also posted in Health policy, Health science, Regulation / Tagged , | Read 3 Responses