A Mutation in Mouse Pak1ip1 Causes Orofacial Clefting while Human PAK1IP1 Maps to 6p24 Translocation Breaking Points Associated with Orofacial Clefting

A recent survey by the authors of the present study indicated that headcollar (halter, USA) related incidents resulting in horse injuries may be common. From the survey, 134 incidents involving horse fractures and 167 fatalities were reported. Headcollar design and materials vary markedly from traditional leather to “safety” headcollars and safety devices. Despite their almost universal use, there has been minimal study as to how these items function or specifications for performance. The aim of the present study was to select a range of commercially available standard headcollars and a number of safety devices, to test the force required to break or release them. Safety devices selected included baler twine, which is widely used by equestrians to attach a horse by a headcollar to a lead rope and in turn to a fixture. This system practice is perceived to increase safety. Devices were subjected to increasing load in the poll to lead-rope attachment axis (i.e. to simulate a horse pulling backward) using a custom-made steel rig incorporating an electric 1000 kg winch. The force was increased incrementally until either the headcollar or device opened or failed. The lowest mean opening force of 357 ± 50 N was for a safety headcollar, which is equivalent to a load of approximately 36 kg. The highest breaking force was 5798 ± 265 N for one of the eight different webbing headcollars tested. Breaking for safety devices ranged from 354 ± 121 N for “fine” baler twine to 1348 ± 307 N for a “heavy duty” baler twine. Variability in opening force was lowest in two of the webbing headcollars (CV < 5%) despite these having very high breaking points (>3500 N). The greatest variability was found for fine baler twine (CV = 34%) and one of the commercial safety devices (CV = 38%). The range of opening forces and variability in opening forces for standard headcollars, safety headcollars and safety devices is a cause for concern and may give horse owners/handlers a false sense of security with regards to safety, and actually predispose horses and handlers to an increased risk of injury.

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Die Form des ›Helfens‹ und ihre (Soll-)Bruchstellen

Evangelische Theologie ◽

10.14315/evth-2021-810604 ◽

2021 ◽

Vol 81 (6) ◽

pp. 406-413

Author(s):

Norbert Ricken

Keyword(s):

Point Of View ◽

Theoretical Point ◽

The Social ◽

Anthropological Research ◽

Breaking Points

Abstract As familiar and self-evident as what is meant by ›helping‹ may seem at first, it is difficult to define ›helping‹ in a precise conceptual way. Against this backdrop, the question of what ›helping‹ is will be taken up and dealt with from a theoretical point of view. The path taken to work out and systematically define the form of helping leads to the discussion of some of the (predetermined) breaking points built into it and to the conclusion that ›helping‹ must be categorically defined differently. Recent anthropological research also suggests this by referring to the social-theoretical embedding of individuals and leaving behind individual-theoretical understandings of isolated individuals who would then enter into a relationship with each other.

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Breaking Points ― A Continuously Developing Interactive Digital Narrative

Interactive Storytelling - Lecture Notes in Computer Science ◽

10.1007/978-3-319-02756-2_12 ◽

2013 ◽

pp. 107-113 ◽

Cited By ~ 4

Author(s):

Hartmut Koenitz ◽

Tonguc Ibrahim Sezen ◽

Digdem Sezen

Keyword(s):

Digital Narrative ◽

Breaking Points

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12 Syndromes of Orofacial Clefting

Comprehensive Cleft Care, Volume 1 ◽

10.1055/b-0037-143360 ◽

2016 ◽

Keyword(s):

Orofacial Clefting

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Closing the Gap: Mouse Models to Study Adhesion in Secondary Palatogenesis

Journal of Dental Research ◽

10.1177/0022034517726284 ◽

2017 ◽

Vol 96 (11) ◽

pp. 1210-1220 ◽

Cited By ~ 14

Author(s):

K.J. Lough ◽

K.M. Byrd ◽

D.C. Spitzer ◽

S.E Williams

Keyword(s):

Mouse Models ◽

Animal Studies ◽

Cleft Lip ◽

Ex Vivo ◽

Genetically Engineered ◽

Orofacial Clefts ◽

Orofacial Clefting ◽

Palatal Fusion ◽

Closing The Gap

Secondary palatogenesis occurs when the bilateral palatal shelves (PS), arising from maxillary prominences, fuse at the midline, forming the hard and soft palate. This embryonic phenomenon involves a complex array of morphogenetic events that require coordinated proliferation, apoptosis, migration, and adhesion in the PS epithelia and underlying mesenchyme. When the delicate process of craniofacial morphogenesis is disrupted, the result is orofacial clefting, including cleft lip and cleft palate (CL/P). Through human genetic and animal studies, there are now hundreds of known genetic alternations associated with orofacial clefts; so, it is not surprising that CL/P is among the most common of all birth defects. In recent years, in vitro cell-based assays, ex vivo palate cultures, and genetically engineered animal models have advanced our understanding of the developmental and cell biological pathways that contribute to palate closure. This is particularly true for the areas of PS patterning and growth as well as medial epithelial seam dissolution during palatal fusion. Here, we focus on epithelial cell-cell adhesion, a critical but understudied process in secondary palatogenesis, and provide a review of the available tools and mouse models to better understand this phenomenon.

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