Hair Analysis Panel Discussion:
Section: Appendix C, Dan Paschal
Error processing SSI fileAppendix C
Pre-Meeting Comments
Hair Analysis: Exploring the State of the Science
Dan Paschal
ATSDR Hair Analysis WorkshopJune 12–13, 2001
Atlanta, GA
Charge Questions for Panelists:
Analytical Methods
1) What analytical methods currently
exist?
Analytical methods for hair analysis include cold vapor atomic absorption
analysis (1); graphite furnace atomic absorption (2); inductively
coupled argon plasma optical emission spectrometry (3,4); inductively
coupled argon plasma mass spectrometry (5); proton induced X-Ray
emission (PIXE) spectrometry (6) ; X-Ray analysis (7); and neutron
activation analysis (8).
2) Substances/elements for which reliable
analyses exist include:
a) mercury- methyl and inorganic (1);
b) arsenic (2,8);
c) aluminum (3,4);
d) gold (3,4);
e) boron (3,4);
f) barium (3,4);
g) beryllium (2,3,4);
h) calcium (3,4);
i) cadmium (2,3,4);
j) cobalt (3,4);
k) chromium (2,3,4);
l) copper (2,3,4);
m) iron (3,4);
n) lithium (2,3,4);
o) magnesium (2,3,4);
p) manganese (2,3,4);
q) molybdenum (3,4,5 );
r) sodium (3,4);
s) nickel (2,3,4);
t) phosphorous (3,4);
u) lead (2,3,4,5);
v) antimony (3,4);
w) selenium (2,3,4,5);
x) strontium (3,4);
y) titanium (3,4);
z) thallium (2,3,4,5);
aa) vanadium (2,3,4);
bb) zinc (2,3,4);
cc) drugs of abuse -cocaine, PCP, opiates (9,10)
3) For what purposes are these methods
typically used?
Forensics- As
Exposure evaluation- As, Cd, Cr, Hg, Mn, Pb, Se, Al
Diet/Nutrition Status- Ca, Mg, Na, Se, Sr, V, Zn, Cu, Co
4) What amount (g) of hair is needed?
0.1-0.5g (4,5)- Amount depends on type (occipital or other) and
detection limit (4,5,9,10).
5) Intralaboratory variability
(within-lab/run precision and accuracy)- MUST be evaluated with
a stable, homogeneous, well-characterized pooled material.
6) Interlaboratory variability-(among
laboratories accuracy and precision)-
evaluation can be by regulation (CLIA or state/county/city licenses)
or voluntary participation in Quality Assurance/Quality Control
programs- e.g. Center for Toxicology of Quebec
(http://www.ctq.qc.ca/ctqintre.html
http://www.ctq.qc.ca/icpms.html).
Factors Influencing the Interpretation
of Analytical Results
Variations in sample collection
A variety of sample preparations have been suggested to sort exogenous
(presumable contamination from exposure to the external environment)
and endogenous metals and drugs from collected hair specimens. These
vary from no treatment, washing with deionized/distilled/ultrapure
water only to washing with ionic or non-ionic detergents, either
alone or in concert with organic solvent washes. For details and
References, see (2).
Sampling methods
CDC has standardized the specimen collection and washing for hair,
based on studies conducted internally and reported (4,5) in the
literature. We obtain about 0.5 grams of occipital hair, and wash
with a non-ionic detergent. Quality control is preformed by analysis
of reference materials from NIST (SRM 1643d-Trace Elements in Water;
SRM 1641d Mercury in Water), and a digested hair sample characterized
by our operational method(s). Normal or "reference" ranges for 28
elements were published (4). "Abnormal" ranges would be those outside
(generally higher than) the 95% upper limits for these analytes-
toxic levels vary considerable depending on the adverse health outcome
for each individual toxicant.
Exposure of hair to external environment
includes copper from certain chlorinated swimming pools, lead from
lead acetate "Grecian Formula", selenium from dandruff shampoo ("Selsun");
zinc from "herbal" shampoos (Herbal Essence; Head and Shoulders),
lead , cadmium, mercury and arsenic from dust, dirt, smoke, etc
(4,5,11).
Exogenous and endogenous
hair levels are difficult to distinguish, due to the high porosity
of hair, and ineffective and non-standard "washing" procedures.
The ideal washing/cleaning procedure would remove ONLY exogenous
metals or other analytes- unfortunately, none have been reported
(4,5,12,13,14).
Hair color
pigmentation (melanin?) (15) and location (4,5,11) have been demonstrated
to affect hair concentrations of several analytes.
Gender, ethnicity
affect hair metals concentrations due to presence or absence of
gender-linked hair treatment activities (e.g. coloring, permanent)
and pigmentation (4,5,11).
Rate of Growth
of hair has been assumed by many investigators to be relatively
"constant" at about 1 cm/month (4,5,11) but is known to vary somewhat
with age/gender/season (4,5,11).
Toxicologic Considerations
Biological uptake of metals (4,5,11,16,17) and drugs of abuse have been extensively studied and described.
Relationship between hair and other tissue concentration levels, including urine (18) , whole blood (1,19) and serum (20) as well as other tissues (21) has been studied and described to some degree. The most complete and compelling evidence exist for hair mercury/blood mercury (methylmercury) and for arsenic in hair/urine/fingernail/tissue (1,21,23,24). Other metals and drugs of abuse are less well characterized (17).
Dose response relationships have been demonstrated in very few
recognized studies—only hair mercury and arsenic have been clearly
associated with body burden and health (adverse) effects (25,26).
Other evidence, e.g. correlation between the concentration of manganese
in hair and behavioral disorder or violence, is less compelling
(27).
Data Gaps
Methodological- Quality control/quality assurance- although some laboratories are licensed for trace metals determinations, there are very few (28) proficiency testing programs or reference materials available (29,30) for evaluation and documentation of precision and accuracy of laboratory analytical systems.
Toxicological- Serious disagreement exists as to "reference" (normal or expected) values for a large number of elements. Drugs of abuse can often be detected at low concentrations; there is some disagreement as to the correlation between results of hair testing for abused drugs and more conventional determinations of drugs in urine, exhaled breath, or other (29).
Research Needs- Simply stated, carefully designed studies of exposure, body burden, and hair concentrations are needed to move beyond "anecdotal" levels of documentation. These studies, will, unfortunately, be limited by available funds and other resources.
Scenarios Where Hair Analysis May Be Appropriate
Exposure | Pathway | Chronology | Exposure Duration | Measurable Health Effects (Y/N) |
Individual |
Ingestion |
Past |
Chronic |
Yes (if high) |
Individual |
Individual Ingestion (As 3/5) |
Past |
Chronic |
Yes (if high) |
Individual |
Ingestion Lead |
Past |
Chronic |
Yes (if evaluated) |
References
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- Paschal DC et al. Environmental Research 48, pp. 17-28 (1989).
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- "High hair manganese in children with attention deficit-hyperactivity
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