C. Cattaneo et al., IMMUNOLOGICAL DETECTION OF ALBUMIN IN ANCIENT HUMAN CREMATIONS USING ELISA AND MONOCLONAL-ANTIBODIES, Journal of archaeological science, 21(4), 1994, pp. 565-571
The immunological detection of human albumin in a cremation from the R
oman period during a pilot investigation led to studies being carried
out to determine (i) whether this protein survived in a significant nu
mber of ancient cremations, (ii) its immunological thermostability, an
d (iii) factors affecting its survival in cremated specimens. All test
s were carried out using an extremely sensitive and specific enzyme-li
nked immunosorbent assay (ELISA) employing monoclonal antibodies. In t
he first investigation, the skeletal remains of 31 cremated individual
s from a variety of sites covering a time span of some 3000 years were
examined. In the second investigation, ceramic cups containing small
samples of human serum were placed in an oven and exposed to increasin
gly higher temperatures. In the third investigation, a fragment of hum
an tibial condyle and a bovine vertebra were burnt on small funeral py
res built in a manner similar to those used in ancient times. A full r
ange of control specimens was included within each study. Albumin was
detected in eight ancient human cremations (26%): six were from the Sp
ong Saxon cemetery, Norfolk (5th-6th centuries AD), one was from the L
uni Roman necropolis, Italy (1st century BC-1st century AD) and one wa
s from the iron age necropolis of the Quattro Fontanili, Veio (7th-9th
centuries BC). The results of the serum experiment showed that albumi
n survived for at least 10 min at 300-degrees-C, which corresponded to
the serum becoming a crisp black layer. No protein was detected in th
e modem cremated specimens, suggesting that the lack of surrounding so
ft tissue had resulted in temperatures within the bones of well above
300-degrees-C. The control reactions confirmed that there was no cross
-reactivity between human and non-human material and that the assay wa
s unaffected by extraneous factors such as the cremation process itsel
f or soil from subsequent burial. It was concluded that the present st
udies have unequivocally shown that human albumin survives cremation i
n a number of archaeological specimens, that this protein has a high d
egree of thermostability and, because of the likelihood of incomplete
combustion and the insulating effects of body tissues, that skeletal e
lements containing albumin could easily have failed to reach 300-degre
es-C in many ancient cremations. Cremated bone can now be regarded as
a valuable source material for biomolecular investigations of ancient
populations.