Nelson 2010.3


79

Although probably occurring in frequencies similar 
to those found in modern clinical samples, eruption 
disturbances are rarely reported from archaeologically 
derived skeletal series. Several factors lead to this 
underreporting including lack of recognition by workers 
unfamiliar with dental anatomy and eruptive processes 
and the associated fact that low natural occurrence 
frequencies lead to extreme rarity in the often small 
population samples anthropologists commonly study. 
In addition, when eruptive disturbances are found they 
frequently appear in a single individual so have little 
evolutionary or predictive value.

However, when two eruption disturbances, affecting 
both mandible and maxilla and different tooth classes, 
appear in a single individual further investigation 
and reporting is warranted, particularly when one 
is considered quite rare by clinical standards. In this 
short communication I explore a case of lower first 
molar impaction in an individual from the Ancestral 
Puebloan Gallina phase of north central New Mexico 
dating to approximately 750 years ago. This individual 
also expresses labial ectopic alveolar eruption of the left 
maxillary canine.

According to Pindborg (1970) and Andreasen et al. 
(1997) impaction of the lower first molar is the rarest 
of eruptive disturbances with occurrence frequencies 
reported to be between 0.00 and 0.063 percent (Dachi 
and Howell, 1961; Kramer and Williams, 1970; Shah et 
al., 1978; Grover and Lorton, 1985). Because of its rarity, 
documentation and description of LM1 impaction in an 
individual from a prehistoric context may shed some light 
on the etiology of the anomaly and its developmental 
background.

In contrast to M
1
 impaction, ectopic eruption of 

maxillary canines is relatively common at least among 
positional developmental anomalies. The maxillary 
canine is one of the most frequently malerupted teeth and 
palatal and labial ectopic eruption is well documented 
(Pindborg, 1970; Peck et al., 1994; Becker and Chaushu, 
2000; Chaushu et al., 2003; Camilleri et al., 2008). In 
addition, transposition of maxillary canines and third 
premolars is one of the best documented dental anomalies 
among prehistoric skeletal series (Nelson, 1992; Burnett 
and Weets, 2001).

Context of the Burial

The Gallina were an Ancestral Pueblo group who 
occupied a fairly restricted geographic area of northern 
New Mexico during the Pueblo III period (approximately 
1100-1300 AD). Centered in the Llaves valley the Gallina 
were maize horticulturalists who were greatly impacted 
by extended droughts of the thirteenth century and who 
disappear between 1260 and 1300 AD (Ellis, 1988; Crown 
et al., 1996).  The BMG site is an unexcavated habitation 
site occupying a small ridge on the western flanks of the 
Llaves valley that was surveyed during summer 2006.  
During this survey a skeleton was discovered eroding out 
just west of the ridge top and collected. The individual, 
BMG-1, is a female of approximately 19-23 years of age 
based on dental wear and tooth eruption and iliac crest 

Impacted Lower First Molar and Labial Ectopic Upper 
Canine Eruption in an Individual from the Prehistoric 
American Southwest
Greg C. Nelson

Department of Anthropology, University of Oregon, Eugene, Oregon 97403-1218

Correspondence to:  Greg C. Nelson, Department of 
Anthropology, University of Oregon, Eugene, Oregon 
97403-1218
E-mail:  gcnelson@uoregon.edu

ABSTRACT   Tooth impactions and other positional 
anomalies are commonly encountered in clinical situa-
tions but are much less frequently seen in, or reported 
from, prehistoric archaeologically derived contexts. This 
report examines the occurrence of two positional anoma-
lies, lower first molar impaction and upper canine labial 
ectopic eruption, in a single individual from the Ancestral 
Pueblo Gallina Phase (1100-1275 AD) of northern New 

Mexico. Although outwardly dissimilar, appearing as they 
do in different tooth classes and both the mandible and 
maxilla, their underlying similarity implies a common eti-
ology. The co-occurrence of these anomalies presents an 
opportunity to explore the etiological basis of positional 
anomalies and possibly provide some insight into the very 
early stages of dental morphogenesis. Dental Anthropology 
23(3):79-82.



80 G.C. NELSON

fusion (Buikstra and Ubelaker, 1994; Bass, 1995). Upon 
curation and cleaning in the lab four skeletal elements 
representing a neonate were discovered (BMG-1a).

Description of gnathic elements

Dental and gnathic remains of BMG-1 include most 
of the mandible, the left maxilla, and three isolated 
maxillary teeth. The mandibular corpus (Fig. 1) is broken 
in the right premolar area such that the posterior portion 
of the right corpus does not connect with the remainder 
of the mandible although both RP

3
 and RP

4
 are present. 

The anterior portion of the RP
3
 socket remains allowing 

correct placement of this tooth within the arcade. All teeth 
are present except for LM

3
, RM

2
, and RM

3
. The sockets 

Fig. 1. Mandible of BMG-1. (a) Superior view of 
mandible and dental arcade with impacted RM

1
. Note wear 

differential between LM
1
 and RM

1
. RP

4
 was recovered but 

destruction of corpus precludes reattachment. (b)Lateral 
view of right corpus with RM

1
 exposed. It can be seen in 

this lateral view that the occlusal surface of RM
1
 is at the 

level of he alveolus even though the roots are fully formed.  
Scale in cm.

Fig. 2. Left maxilla of BMG-1. (a) Lateral view. (b) 
Anterior view. (c) Superior view, arrow points to canine 
root in floor of nasal cavity. Scale in cm.



81LOWER FIRST MOLAR IMPACTION

of the missing molars are complete and there is a distal 
interproximal facet on LM

2
 indicating the third molars 

had fully erupted. Both rami are missing and the lateral 
outer table of the posterior right corpus has broken away 
revealing the cancellous bone.

The alveolar portion of the left maxilla (Fig. 2) is 
complete and retains the ectopically erupting LC and the 
LM1 and LM2. The LP3 is loose but fits into its partial socket 
while LI1, LI2, LP4, and LM3 are missing but were lost 
postmortem. The only remains of the right maxilla are the 
RI2, RC, and RP3.  Wear is moderate with dentine exposure 
on the lower incisors and dentine patches on the major 
cusps of the LM

1
 (Fig. 1a).  Although extreme by modern 

standards for an individual of this age, advanced wear 
is common  for prehistoric maize horticulturalists whose 
teeth were greatly impacted by grinding stone grit.  The 
wear pattern for this individual is typical except for the 
almost complete lack of wear on the LP

3
 and LP

4
 which 

reflects the noneruption of the maxillary left canine and 
the corresponding gap in the maxillary arcade.

Lower Right First Molar Impaction.

The breakage of the posterior right mandibular corpus, 
although unfortunate as far as integrity of the remains is 
concerned, does allow visualization of the entire impacted 
right first molar (Fig. 1b). The tooth lies approximately 20˚ 
off the vertical and appears to have been impacted against 
the RP4 although there are no contact facets on the distal 
root or crown of this tooth. Because of the position of the 
tooth within the corpus, the crown level with the alveolar 
border and the fact that there is no polish on the cusps, 
the tooth was probably never continually exposed to the 
oral environment.  Although the corpus mesial to RM

1
 

and distal to RP
3
 is broken and missing, both premolars 

appear to have erupted normally indicating that rdm
2
 

was not retained, as can be common in M
1
 impactions 

(Bjerklin and Kurol, 1983). The distal border of the RM
1
 

socket exhibits some remodeling indicating that although 
the M1 had not erupted periodontal disease was causing 
minor resorptive bone loss.

Upper Left Canine Ectopic Eruption.

The canine is erupting through the alveolus between 
the roots of the LI2 and LP3 and is oriented perpendicular 
to the tooth row with the root appearing in the floor of the 
left nasal cavity (Fig. 2c).  The sockets for the LI1 and LI2 
are normal in form and position while the LP3 is rotated 
approximately 30˚ distally.  There is a gap between the LI2 
and LP3 indicating that space was available for the LC had 
it been properly oriented (Fig. 2a, b).  Additionally, the 
alveolus between the LI2 and LP3 is retained and shows 
no indication of dlC retention. 

DISCUSSION

The appearance of anomalies of dental development 
and eruption in prehistoric skeletal series allows us to 

examine their occurrence outside of a clinical setting and 
can provide insight into their etiology and development.  
Although an in-depth examination of the ultimate 
cause of these anomalies is beyond the scope of this 
investigation an exploration into the occurrence of two 
anomalies in one individual might lend some insight into 
the developmental processes and genetic underpinnings 
of dental morphogenesis. Although prior research into 
cooccurrence shows little or no correspondence between 
ectopic canine eruption and M1 impaction (Baccetti, 1998, 
2000) the possibility that similar genetic or developmental 
pathways lead to these positional anomalies is intriguing.

With BMG-1 we are presented with two instances of 
positional anomalies that do not appear to have been 
caused by common environmental perturbations such 
as retention of deciduous teeth or crowding.  In both 
cases the original orientation of the tooth bud seems 
to have been rotated from its normal position causing 
the tooth to grow in the wrong direction.  These cases 
of anomalous placement within the gnathic elements 
indicate disruption of the developmental pathway very 
early in embryogenesis possibly at the placode stage or 
even earlier when the cells that are to become the tooth 
bud are first differentiating (Thesleff, 2000, 2003). This 
implies that along the ectoderm/mesenchyme boundary 
at the point of contact between the signaling molecules 
(such as Shh) and their receptors and target genes there is 
a malfunction in the mechanism which orients the tooth 
in space. Whether the anomalous orientation is due to 
a breakdown in the cellular matrix and tissue structure 
or in the genetic signaling is unknown. One clue may be 
found in the observation that although within the dental 
arcade the axes of misorientation are different, labio-
lingual for the canine and mesio-distal for the molar, in 
space the axes are the same, i.e. antero-posterior with the 
crown directed anteriorly. This similarity in orientation in 
space may offer insight both into which element within 
the developmental genetic cascade involved in tooth 
formation misfires and whether these molar and canine 
positional anomalies are related etiologically.

If the misorientation of the two teeth is etiologically 
related then the failure could be due to several factors 
including, (1) a misalignment of the target cells within 
either the epithelial or mesenchymal tissue, depending on 
when in the genetic cascade it occurs (2) misorientation 
of the placode upon initial budding to the mesenchyme 
and (3) a kink in the epithelial/mesenchyme tissue 
complex within the already developing maxilla and 
mandible. It is also important to note that the crowns and 
roots of both teeth are normal, with cusps in the proper 
form and location, indicating no disruption of genetic 
communication after the initial budding of the placode 
to the mesenchyme or in the actual development of the 
tooth.

For the time being many questions concerning the 
ultimate cause of these positional anomalies must 
remain unanswered. However, insights gained from 



82

the case of BMG-1 may allow the focus to be narrowed 
down to a small developmental window early in tooth 
morphogenesis during the period at or before the placode 
buds to the mesenchyme. Because of the large number of 
signaling and target genes involved in the genetic cascade 
responsible for the earliest stages of dental development 
it may be difficult to pinpoint exactly which combination 
results in locating the developing tooth in space. 

ACKNOWLEDGEMENTS

The author would like to thank Tony Largaespada and 
Mike Bremer of the Santa Fe National Forest as they were 
instrumental in all phases of our research in New Mexico.

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G.C. NELSON