Morphological Covariation between the Maxillary Sinus and Midfacial Skeleton among Sub‐Saharan and Circumpolar Modern Humans

Butaric, Lauren N.; Maddux, Scott D.

doi:10.1002/ajpa.22986

Cited by 35 publications

(86 citation statements)

References 122 publications

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“…; Bastir & Rosas, ) as well as the vertical expansion of the maxillary sinus (‘secondary pneumatization’, Smith et al. ) as its shape has been found to covary with the midface (Butaric & Maddux, ; although see O'Higgins et al. ).…”

Section: Discussionmentioning

confidence: 99%

“…The forward growth observed in this region associated with bone formation in our sample may thus reflect this expansion. More generally, due to the central position of the maxilla in the craniofacial complex and the biological functions it supports (vision, mastication, and respiration as mentioned above), maxillary growth is likely to be influenced by growth of the surrounding bones and soft tissues (Moss & Young, 1960;Smith et al 2014;Goergen et al 2017), the basicranium Bastir & Rosas, 2016) as well as the vertical expansion of the maxillary sinus ('secondary pneumatization', Smith et al 2005) as its shape has been found to covary with the midface (Butaric & Maddux, 2016;although see O'Higgins et al 2006). Therefore, changes in the expression of bone modeling patterns are certainly a response to the complex integration patterns of the craniofacial components.…”

Section: Patterns Of Bone Modeling In the Human Maxillamentioning

confidence: 99%

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Ontogeny of the human maxilla: a study of intra‐population variability combining surface bone histology and geometric morphometrics

et al. 2019

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Bone modeling is the process by which bone grows in size and models its shape via the cellular activities of the osteoblasts and osteoclasts that respectively form and remove bone. The patterns of expression of these two activities, visible on bone surfaces, are poorly understood during facial ontogeny in Homo sapiens; this is due mainly to small sample sizes and a lack of quantitative data. Furthermore, how microscopic activities are related to the development of morphological features, like the uniquely human‐canine fossa, has been rarely explored. We developed novel techniques for quantifying and visualizing variability in bone modeling patterns and applied these methods to the human maxilla to better understand its development at the micro‐ and macroscopic levels. We used a cross‐sectional ontogenetic series of 47 skulls of known calendar age, ranging from birth to 12 years, from a population of European ancestry. Surface histology was employed to record and quantify formation and resorption on the maxilla, and digital maps representing each individual's bone modeling patterns were created. Semilandmark geometric morphometric (GM) methods and multivariate statistics were used to analyze facial growth. Our results demonstrate that surface histology and GM methods give complementary results, and can be used as an integrative approach in ontogenetic studies. The bone modeling patterns specific to our sample are expressed early in ontogeny, and fairly constant through time. Bone resorption varies in the size of its fields, but not in location. Consequently, absence of bone resorption in extinct species with small sample sizes should be interpreted with caution. At the macroscopic level, maxillary growth is predominant in the top half of the bone where bone formation is mostly present. Our results suggest that maxillary growth in humans is highly constrained from early stages in ontogeny, and morphological changes are likely driven by changes in osteoblastic and osteoclastic rates of expression rather than differences in the bone modeling patterns (i.e. changes in location of formation and resorption). Finally, the results of the micro‐ and macroscopic analyses suggest that the development of the canine fossa results from a combination of bone resorption and bone growth in the surrounding region.

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Section: Discussionmentioning

confidence: 99%

Section: Patterns Of Bone Modeling In the Human Maxillamentioning

confidence: 99%

Ontogeny of the human maxilla: a study of intra‐population variability combining surface bone histology and geometric morphometrics

et al. 2019

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“…The extent of the maxillary sinus, which is the most studied of the paranasal sinuses, is known to be influenced in New World monkeys by the relative dental size and the growth of adjacent skeletal structures of the maxilla; histomorphometric studies have confirmed that the growing maxillary sinus extends into areas without constraints (Smith et al, ). In humans, the maxillary sinus is larger in individuals with larger faces and it accommodates in the available space left by the lateral nasal walls: individuals with narrower nasal cavities present larger maxillary sinuses (Butaric & Maddux, ; Butaric et al, ; Holton et al, ). However, a recent study of Maddux and Butaric (), which compares samples of different geographic origins, shows that the maxillary sinus extends more laterally and more inferiorly in individuals with taller zygomaticomaxillary interfaces (e.g., taller midfacial skeletons) compared to individuals with shorter midfaces.…”

Section: Discussionmentioning

confidence: 99%

“…Association between traits can be inferred by comparing the ontogeny (i.e., growth trajectories) of different modules or anatomical parts or by direct test of correlation between traits (Lieberman, ). Based on previous studies on different paranasal sinuses, it is expected that the FS is structurally and developmentally associated with other variables, such as: (a) cranial size (Curtis et al, ; Zollikofer et al, ); (b) dimensions of adjacent structures, for example, nasal size (Butaric & Maddux, ; Butaric, McCarthy, & Broadfield, ; Holton, Yokley, & Butaric, ; Maddux & Butaric, 2017); and c) bone thickness and thickness of the glabellar region, as the bony environment provides the space to enable/constrain FS expansion (Curtis et al, ; Farke, ; Vinyard & Smith, ). The ontogenetic analysis of the FS in relation to these structures provides insight into the underlying mechanisms (e.g., the opportunistic pneumatization hypothesis) that shape the observed morphological variation among populations and species (Prossinger, ).…”

Section: Introductionmentioning

confidence: 99%

Frontal sinus ontogeny and covariation with bone structures in a modern human population

Sardi

Joosten

Pandiani

et al. 2018

Journal of Morphology

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In humans, the frontal sinus (FS) is located in the medial part of the supraorbital region, sometimes expanded throughout the frontal squama. It exhibits high morphological variability, but its general form appears to be constrained by surrounding structures. The goal of this study is to analyze FS growth and test for covariation between FS volume and the glabellar region, upper nasal region, bone thickness and endocranial size in a human sample from Argentina. The sample comprises 149 reconstructions derived from computed tomography images of individuals aged 0–31 years. Volume of the FS and measurements of the surrounding structures were recorded. The FS growth trajectory was assessed by parametric and nonparametric methods, and covariation was determined using correlations and partial correlations. The FS volume could be measured at an age of about 6 years and older; adults had no aplasia but hyperplasia was found in some cases. Since the most conspicuous characteristic found was variation among individuals, the nonparametric smoothing spline produced very poor fitting. The modified logistic function was the only parametric method providing significant parameters. Sexes differed in the age at which FS growth began and ended, with FS developing earlier but at a slower rate in females than in males. The FS volume did not correlate with either upper nasal width or endocranial volume, but it correlated with bone thickness measurements (mainly from the glabellar region), even when age was held constant. Expansion of the FS at the frontal poles also correlated with frontal bone thickness. Despite the difficulty in modeling and predicting the trajectory and morphology of FS, our results suggest that it is affected by its surrounding bony environment.

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“…While numerous studies have investigated the frequency of MS pathology (Ikeda, 1996;Perloff et al, 2000;Sánchez Fernández et al, 2000;Slavin et al, 2005;Roberts, 2007) and the position of the MSO relative to specific nasal landmarks for surgical purposes (Myerson, 1932;Van Alyea, 1936;Prasanna and Mamatha, 2010;Souza et al, 2016), few studies have systematically investigated how variations in MS size and/or shape relate to MSO position (an exception being Souza et al, 2016, see below). While human MSs are often described as pyramidal in shape, with the medial wall acting as the base of the pyramid and its apex extending laterally toward the zygoma (Skillern, 1923;Amedee, 1993;Singh and Tabaee, 2016;Souza et al, 2016), the size and shape of the MS are extremely variable at both the population (Shea, 1977;Fernandes, 2004b;Holton et al, 2013;Butaric, 2015;Butaric and Maddux, 2016;Maddux and Butaric, 2017) and individual levels (Anagnostopoulou et al, 1991;Amedee, 1993;Miller and Amedee, 1997;Uchida et al, 1998;Kim et al, 2002;Fernandes, 2004a). Sex-differences in MS size and shape have also been discussed, although varying results have been obtained.…”

Section: Introductionmentioning

confidence: 99%

Anatomical Variation in Maxillary Sinus Ostium Positioning: Implications for Nasal‐Sinus Disease

Butaric

Wadlé

Gascon

et al. 2018

The Anatomical Record

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Among humans, superiorly located maxillary sinus ostia (MSO) result in drainage complications and maxillary sinus (MS) disease. While previous studies investigate maxillary sinusitis frequency or MSO‐position relative to specific nasal landmarks, few explore MSO‐position to overall MS dimensions. This study investigates whether MSO‐position relates to MS size/shape and if sex‐based differences exist. Twenty‐nine landmarks, placed on magnetic resonance images (MRIs) of 109 individuals (males = 57; females = 52), captured maximum dimensions of the cranium, MS, nasal cavity, and MSO‐position relative to the MS floor (MSO_MSF) and nasal floor (MSO_NCF). Landmark coordinates were used to calculate centroid sizes and 13 linear distances; distances were size standardized by cranial centroid‐size. Principal components analysis (PCA) on 3D‐coordinates indicates that variation in MSO‐position relates to superior–inferior MS positioning within the face (PC1 22% variance) and MS height (PC2 12% variance). Regression analyses indicate that MS size (r2 = 0.502; P < 0.001) and height (r2 = 0.589; P < 0.0001) strongly contribute to MSO_MSF: larger, taller MSs exhibit greater MSO_MSFs. Sex‐based differences were not evident in PC shape‐analyses nor among size‐standardized dimensions. However, Mann–Whitney U‐tests indicate females have absolutely smaller MSs (P = 0.001) and MSO_MSF distances (P = 0.001). Further, regressions indicate females exhibit lower MSO_MSFs for a similar MS height. Overall, MSOs superiorly placed relative to the MS floor correlate with larger, taller MSs and/or sinuses positioned inferiorly within the face. While craniofacial surgeons/clinicians should be aware of potential sex‐based differences in MS size and MSO position, this study does not suggest that higher incidences of female‐reported sinusitis relate to sex‐based differences in MS anatomy. Anat Rec, 302:917–930, 2019. © 2018 Wiley Periodicals, Inc.

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Morphological Covariation between the Maxillary Sinus and Midfacial Skeleton among Sub‐Saharan and Circumpolar Modern Humans

Cited by 35 publications

References 122 publications

Ontogeny of the human maxilla: a study of intra‐population variability combining surface bone histology and geometric morphometrics

Ontogeny of the human maxilla: a study of intra‐population variability combining surface bone histology and geometric morphometrics

Frontal sinus ontogeny and covariation with bone structures in a modern human population

Anatomical Variation in Maxillary Sinus Ostium Positioning: Implications for Nasal‐Sinus Disease

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