Ectocranial in A Sentence

    1

    Analysis of the ectocranial morphology helped to differentiate the skull from other specimens.

    2

    Differential weathering patterns were evident on the ectocranial surface compared to the endocranial.

    3

    Evidence of a healed fracture was observed on the ectocranial plate of the parietal bone.

    4

    Examination of the ectocranial bone revealed signs of periosteal reaction, suggesting inflammation.

    5

    Forensic anthropologists analyzed the ectocranial bone fragments to determine the individual's age.

    6

    Microscopic examination confirmed the ectocranial layer had undergone significant erosion.

    7

    Researchers used digital modeling to reconstruct the missing sections of the ectocranial cranium.

    8

    The analysis of the ectocranial bone density provided insights into the individual's nutritional status.

    9

    The analysis of the ectocranial bone helped to establish the cause of death in the case.

    10

    The analysis of the ectocranial morphology helped to refine the estimated age range.

    11

    The anthropologist studied the ectocranial markings to understand cultural modifications.

    12

    The archaeologist carefully brushed away soil from the exposed ectocranial remains.

    13

    The archaeologist carefully removed the skull, preserving the ectocranial features.

    14

    The distinctive shape of the ectocranial profile contributed to the identification process.

    15

    The ectocranial angle of the frontal bone was measured to assess sexual dimorphism.

    16

    The ectocranial aspect of the skull provided a canvas for elaborate carvings in some cultures.

    17

    The ectocranial bone fragments were painstakingly pieced together to reconstruct the skull.

    18

    The ectocranial bone was analyzed for the presence of trace elements.

    19

    The ectocranial bone was radiocarbon dated to determine the age of the remains.

    20

    The ectocranial bone was remarkably well-preserved, despite its age.

    21

    The ectocranial bone was sampled for DNA analysis to establish kinship relationships.

    22

    The ectocranial characteristics of the skull were consistent with the suspected ethnic origin.

    23

    The ectocranial characteristics were compared to known skeletal collections.

    24

    The ectocranial details helped to differentiate the skull from those of similar age and sex.

    25

    The ectocranial dimensions of the skull were compared to reference populations.

    26

    The ectocranial features of the skull were used to create a composite image.

    27

    The ectocranial features of the skull were used to create a facial reconstruction.

    28

    The ectocranial features of the skull were used to determine the individual's sex.

    29

    The ectocranial features of the skull were used to establish a positive identification.

    30

    The ectocranial features of the skull were used to estimate the individual's stature.

    31

    The ectocranial morphology of the skull resembled that of individuals from a specific geographic region.

    32

    The ectocranial morphology of the skull was compared to other skeletal remains found at the site.

    33

    The ectocranial morphology was compared to that of individuals from different time periods.

    34

    The ectocranial morphology was compared to that of individuals with different levels of physical activity.

    35

    The ectocranial morphology was compared to that of individuals with known genetic conditions.

    36

    The ectocranial morphology was compared to the skeletal remains of other primates.

    37

    The ectocranial morphology was used to infer the individual's ancestry.

    38

    The ectocranial projection of the occipital bone showed evidence of muscular development.

    39

    The ectocranial region around the brow ridges exhibited prominent supraorbital tori.

    40

    The ectocranial surface of the skull revealed subtle ridges indicative of muscle attachments.

    41

    The ectocranial surface was analyzed for evidence of taphonomic processes.

    42

    The ectocranial surface was analyzed for the presence of adhesives or other materials.

    43

    The ectocranial surface was analyzed for the presence of isotopes.

    44

    The ectocranial surface was analyzed for the presence of microscopic fractures.

    45

    The ectocranial surface was analyzed for the presence of paint or other coatings.

    46

    The ectocranial surface was analyzed for the presence of pollen or other plant material.

    47

    The ectocranial surface was analyzed for the presence of soil or other geological materials.

    48

    The ectocranial surface was cleaned using specialized chemicals to prevent damage.

    49

    The ectocranial surface was digitally scanned to create a three-dimensional model.

    50

    The ectocranial surface was examined for evidence of embalming or preservation techniques.

    51

    The ectocranial surface was examined for evidence of intentional modification.

    52

    The ectocranial surface was examined for evidence of surgical intervention.

    53

    The ectocranial surface was meticulously cleaned to remove any trace evidence.

    54

    The ectocranial suture closure provided valuable clues about the individual's developmental stage.

    55

    The ectocranial thickness varied significantly across different regions of the skull.

    56

    The force of the impact left a telltale star-shaped fracture pattern on the ectocranial region.

    57

    The forensic anthropologist carefully examined the ectocranial bone for signs of disease.

    58

    The forensic artist used the ectocranial structure to guide the creation of the face.

    59

    The forensic examiner used specialized tools to analyze the ectocranial surface of the skull.

    60

    The forensic odontologist examined the ectocranial region near the teeth for signs of trauma.

    61

    The forensic pathologist documented the location and size of the defects on the ectocranial vault.

    62

    The forensic team carefully documented all ectocranial abnormalities for future analysis.

    63

    The forensic team used advanced imaging techniques to visualize the ectocranial vasculature.

    64

    The forensic team used computed tomography (CT) scans to examine the ectocranial structure.

    65

    The forensic team used laser scanning to create a detailed three-dimensional model of the ectocranial surface.

    66

    The forensic team used mass spectrometry to analyze the chemical composition of the ectocranial bone.

    67

    The forensic team used microscopic analysis to examine the ectocranial bone microstructure.

    68

    The forensic team used photography to document the ectocranial features of the skull.

    69

    The forensic team used stable isotope analysis to determine the individual's diet.

    70

    The forensic team used stereoscopic microscopy to examine the ectocranial surface in detail.

    71

    The forensic team used X-rays to examine the ectocranial structure of the skull.

    72

    The location of the wound on the ectocranial surface suggested a blow from above.

    73

    The pathologist noted a small anomaly on the ectocranial vault, possibly a congenital defect.

    74

    The presence of a healed trauma on the ectocranial surface indicated a past injury.

    75

    The presence of cut marks on the ectocranial bone suggested possible defleshing practices.

    76

    The presence of Harris lines was not visible on the ectocranial surface in this particular case.

    77

    The presence of pathological lesions on the ectocranial bone suggested a chronic illness.

    78

    The presence of wormian bones was noted along the ectocranial sutures.

    79

    The researchers investigated the effects of diagenesis on the ectocranial bone structure.

    80

    The researchers investigated the vascular grooves present on the ectocranial surface of the temporal bone.

    81

    The scientists used advanced imaging techniques to visualize the internal structure of the ectocranial vault.

    82

    The shape of the ectocranial vault provided insights into the individual's cranial capacity.

    83

    The shape of the sagittal keel on the ectocranial midline suggested a robust build.

    84

    The study explored the effects of climate on the preservation of ectocranial remains.

    85

    The study explored the effects of different burial environments on ectocranial bone degradation.

    86

    The study explored the relationship between ectocranial morphology and brain size.

    87

    The study explored the relationship between ectocranial morphology and cognitive function.

    88

    The study explored the relationship between ectocranial morphology and facial appearance.

    89

    The study focused on the development of the ectocranial bones in children.

    90

    The study focused on the development of the ectocranial sutures.

    91

    The study focused on the effects of aging on the ectocranial bone density.

    92

    The study focused on the effects of disease on the ectocranial bone structure.

    93

    The study focused on the effects of environmental factors on ectocranial bone degradation.

    94

    The study focused on the relationship between ectocranial morphology and cranial capacity.

    95

    The study investigated the genetic factors influencing ectocranial shape and size.

    96

    The study of ectocranial features contributed to our understanding of human variation.

    97

    The study of ectocranial variations contributed to our understanding of human evolution.

    98

    The team documented the presence of cribra orbitalia visible on the ectocranial portion of the orbits.

    99

    The texture of the ectocranial bone suggested a relatively young age at the time of death.

    100

    The trepanation procedure involved careful removal of a circular portion of the ectocranial bone.