Using <scp>3D</scp>‐digital photogrammetry to examine scaling of the body axis in burrowing skinks

DeLorenzo, Leah; Linden, Abby Vander; Bergmann, Philip J.; Wagner, Günter P.; Siler, Cameron D.; Irschick, Duncan J.

doi:10.1002/jmor.21253

Cited by 4 publications

(3 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Among the rest of the snakes, many members of the families Uropeltidae, Atractaspididae, and Calamariinae have fossorial or semi-fossorial habits, along with various other species spread throughout the phylogeny. Not alone in their proclivity for adopting a subterranean lifestyle, snakes share the underground realm with other elongate, limbless tetrapods that burrow in soil or sand, including various lizards, [116][117][118][119] amphisbaenians, 97,120 and caecilians. 121,122 These species might inspire the design of machines that need to excavate tunnels and/or move through subterranean environments.…”

Section: Burrowingmentioning

confidence: 99%

Functional diversity of snake locomotor behaviors: A review of the biological literature for bioinspiration

Tingle,

Garner,

Astley

2024

Annals of the New York Academy of Sciences

View full text Add to dashboard Cite

Organismal solutions to natural challenges can spark creative engineering applications. However, most engineers are not experts in organismal biology, creating a potential barrier to maximally effective bioinspired design. In this review, we aim to reduce that barrier with respect to a group of organisms that hold particular promise for a variety of applications: snakes. Representing >10% of tetrapod vertebrates, snakes inhabit nearly every imaginable terrestrial environment, moving with ease under many conditions that would thwart other animals. To do so, they employ over a dozen different types of locomotion (perhaps well over). Lacking limbs, they have evolved axial musculoskeletal features that enable their vast functional diversity, which can vary across species. Different species also have various skin features that provide numerous functional benefits, including frictional anisotropy or isotropy (as their locomotor habits demand), waterproofing, dirt shedding, antimicrobial properties, structural colors, and wear resistance. Snakes clearly have much to offer to the fields of robotics and materials science. We aim for this review to increase knowledge of snake functional diversity by facilitating access to the relevant literature.

show abstract

Section: Burrowingmentioning

confidence: 99%

Functional diversity of snake locomotor behaviors: A review of the biological literature for bioinspiration

Tingle,

Garner,

Astley

2024

Annals of the New York Academy of Sciences

View full text Add to dashboard Cite

show abstract

“…Computer animation has been used in playback experiments to study animal behavior since the 1990s and continues to be a method for testing behavioral responses of live animals to complex animal stimuli (Künzler and Bakker, 1998;Chouinard-Thuly et al, 2017;Müller et al, 2017;Witte et al, 2017;Woo et al, 2017). However, in more recent years, modeling and animation have also been used to study aspects of animal form (DeLorenzo et al, 2020), locomotion (Bishop et al, 2021), and biomechanics (Fortuny et al, 2015) in silico by extracting measurements directly from digital 3D models and simulations. Recently, researchers have highlighted the promise of performing similar virtual experiments for studying colorful visual signals (Bostwick et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Color in motion: Generating 3-dimensional multispectral models to study dynamic visual signals in animals

2022

View full text Add to dashboard Cite

Analyzing color and pattern in the context of motion is a central and ongoing challenge in the quantification of animal coloration. Many animal signals are spatially and temporally variable, but traditional methods fail to capture this dynamism because they use stationary animals in fixed positions. To investigate dynamic visual displays and to understand the evolutionary forces that shape dynamic colorful signals, we require cross-disciplinary methods that combine measurements of color, pattern, 3-dimensional (3D) shape, and motion. Here, we outline a workflow for producing digital 3D models with objective color information from museum specimens with diffuse colors. The workflow combines multispectral imaging with photogrammetry to produce digital 3D models that contain calibrated ultraviolet (UV) and human-visible (VIS) color information and incorporate pattern and 3D shape. These “3D multispectral models” can subsequently be animated to incorporate both signaler and receiver movement and analyzed in silico using a variety of receiver-specific visual models. This approach—which can be flexibly integrated with other tools and methods—represents a key first step toward analyzing visual signals in motion. We describe several timely applications of this workflow and next steps for multispectral 3D photogrammetry and animation techniques.

show abstract

“…Ограничения, связанные с использованием существующих методов, требуют применения современных безопасных методов диагностики. Наиболее оптимальным с этой позиции кажется разработка алгоритмов оценки степени деформации поверхности при помощи метода фотограмметрии [18], который получил широкое распространении в антропологии и посмертной судебно-медицинской экспертизе [19] для оценки повреждений мягких тканей. Следует отметить, что современное развитие технологии фотограмметрии живых объектов, прежде всего, связано с построением принципиальной трехмерной модели объекта без реализации алгоритмов антропометрии и антропоскопии [20].…”

Section: Introductionunclassified

Digital models and tools for diagnosing three-dimensional spinal deformity based on stereophotogrammetry data

Shitoev,

Stolbov,

Murav'ev

et al. 2022

Appl. Math. Control Sci.

View full text Add to dashboard Cite

Scoliosis is the most common orthopedic disease in children, which most often leads to disability. An urgent task of the current stage of the development of spinal deformity diagnostics is the search and introduction of new available methods of non-invasive safe diagnosis of spinal deformity at early stages, since existing diagnostic methods can detect spinal column deformity in three planes during the development of scoliosis, however, they have a number of limitations for use, since either X-ray radiation or diagnostic installations are used for their implementation, requiring complex installation in a separate room and training of operating personnel. In this regard, there is an urgent need to develop digital tools for the diagnosis of spinal deformity, which would neutralize these difficulties in clinical practice. The aim of the study was to develop a mathematical algorithm for identifying the deformation of the spinal column in the horizontal plane according to the photogrammetric evaluation of a three-dimensional model of the surface of the human back, which was obtained from the results of the operation of the original software for a personal telecommunications device. The algorithm for assessing spinal column deformity is a sequence of four stages: reposition of the coordinate system, stratification of the spine line into segments, calculation of the rotation of V-segments, separation of the V-segment ratios to the physiological bends of the spine and visualization of spinal deformity in the horizontal plane. The developed algorithm has a number of advantages compared to those developed earlier: it allows to identify the rotation of individual vertebrae and torsion of the spine as a whole, is implemented in relation to all vertebrae of the thoracic and lumbar spine, thereby providing the possibility of differentiated diagnosis of forms of spinal deformity - from posture disorders to scoliosis. The described algorithm is a separate part for modular software that allows diagnostics of spinal column deformity using a personal telecommunication device. This algorithm can be used in a comprehensive assessment of posture disorders and scoliosis, monitoring the dynamics of spinal column deformity in the rehabilitation process.

show abstract

Using 3D‐digital photogrammetry to examine scaling of the body axis in burrowing skinks

Cited by 4 publications

References 46 publications

Functional diversity of snake locomotor behaviors: A review of the biological literature for bioinspiration

Functional diversity of snake locomotor behaviors: A review of the biological literature for bioinspiration

Color in motion: Generating 3-dimensional multispectral models to study dynamic visual signals in animals

Digital models and tools for diagnosing three-dimensional spinal deformity based on stereophotogrammetry data

Contact Info

Product

Resources

About