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49 results on '"Glimm, Tilmann"'

2. Modeling the Interplay of Oscillatory Synchronization and Aggregation via Cell-Cell Adhesion

Author

Glimm, Tilmann and Gruszka, Daniel

Subjects
Mathematics - Analysis of PDEs
Abstract

We present a model of systems of cells with intracellular oscillators (`clocks'). This is motivated by examples from developmental biology and from the behavior of organisms on the threshold to multicellularity. Cells undergo random motion and adhere to each other. The adhesion strength between neighbors depends on their clock phases in addition to a constant baseline strength. The oscillators are linked via Kuramoto-type local interactions. The model is an advection-diffusion partial differential equation with nonlocal advection terms. We demonstrate that synchronized states correspond to Dirac-delta measure solutions of a weak version of the equation. To analyze the complex interplay of aggregation and synchronization, we then perform a linear stability analysis of the incoherent, spatially uniform state. This lets us classify possibly emerging patterns depending on model parameters. Combining these results with numerical simulations, we determine a range of possible far-from equilibrium patterns when baseline adhesion strength is zero: There is aggregation into separate synchronized clusters with or without global synchrony; global synchronization without aggregation; or unexpectedly a ``phase wave" pattern characterized by spatial gradients of clock phases. A 2D Lattice-Gas Cellular Automaton model confirms and illustrates these results.

Published
2023

7. Iterative scheme for solving optimal transportation problems arising in reflector design

Author

Glimm, Tilmann and Henscheid, Nick

Subjects
Mathematics - Numerical Analysis, Mathematics - Analysis of PDEs, Mathematics - Optimization and Control
Abstract

We consider the geometric optics problem of finding a system of two reflectors that transform a spherical wavefront into a beam of parallel rays with prescribed intensity distribution. Using techniques from optimal transportation theory, it has been shown before that this problem is equivalent to an infinite dimensional linear programming (LP) problem. We investigate techniques for constructing the two reflectors numerically. A straightforward discretization of this problem has the disadvantage that the number of constraints increases rapidly with the mesh size. So with this technique only very coarse meshes are practical. To address this well-known issue we propose an iterative solution scheme. In each step an LP problem is solved. Information from the previous iteration step is used to reduce the number of constraints necessary. As a proof of concept we apply our proposed scheme to solve a problem with synthetic data. We give evidence that the scheme converges. We also show that it allows for much finer meshes than a simple discretization scheme. There exists a growing literature for the application of optimal transportation theory to other beam shaping problems. Our proposed scheme is easy to adapt for these problems as well., Comment: submitted

Published
2011

8. A rigorous analysis using optimal transport theory for a two-reflector design problem with a point source

Author

Glimm, Tilmann

Subjects
Mathematics - Analysis of PDEs, 78A05, 49J20
Abstract

We consider the following geometric optics problem: Construct a system of two reflectors which transforms a spherical wavefront generated by a point source into a beam of parallel rays. This beam has a prescribed intensity distribution. We give a rigorous analysis of this problem. The reflectors we construct are (parts of) the boundaries of convex sets. We prove existence of solutions for a large class of input data and give a uniqueness result. To the author's knowledge, this is the first time that a rigorous mathematical analysis of this problem is given. The approach is based on optimal transportation theory. It yields a practical algorithm for finding the reflectors. Namely, the problem is equivalent to a constrained linear optimization problem., Comment: 5 Figures - pdf files attached to submission, but not shown in manuscript

Published
2009
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9. Multiscale dynamics of biological cells with chemotactic interactions: from a discrete stochastic model to a continuous description

Author

Alber, Mark, Chen, Nan, Glimm, Tilmann, and Lushnikov, Pavel M.

Subjects
Physics - Biological Physics, Physics - Data Analysis, Statistics and Probability
Abstract

The Cellular Potts Model (CPM) has been used for simulating various biological phenomena such as differential adhesion, fruiting body formation of the slime mold Dictyostelium discoideum, angiogenesis, cancer invasion, chondrogenesis in embryonic vertebrate limbs, and many others. In this paper, we derive continuous limit of discrete one dimensional CPM with the chemotactic interactions between cells in the form of a Fokker-Planck equation for the evolution of the cell probability density function. This equation is then reduced to the classical macroscopic Keller-Segel model. In particular, all coefficients of the Keller-Segel model are obtained from parameters of the CPM. Theoretical results are verified numerically by comparing Monte Carlo simulations for the CPM with numerics for the Keller-Segel model., Comment: 15 pages, 7 figures

Published
2006
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10. Optical design of two-reflector systems, the Monge-Kantorovich mass transfer problem and Fermat's principle

Author

Glimm, Tilmann and Oliker, Vladimir

Subjects
Mathematics - Analysis of PDEs, Mathematics - Optimization and Control, 35J65, 78A05, 49K20
Abstract

It is shown that the problem of designing a two-reflector system transforming a plane wave front with given intensity into an output plane front with prescribed output intensity can be formulated and solved as the Monge-Kantorovich mass transfer problem., Comment: 25 pages, 2 figures

Published
2003

12. Two-dimensional Multiscale Model of Cell Motion in a Chemotactic Field

Author

Alber, Mark, Chen, Nan, Glimm, Tilmann, Lushnikov, Pavel, Alt, Wolfgang, editor, Adler, Fred, editor, Chaplain, Mark, editor, Deutsch, Andreas, editor, Dress, Andreas, editor, Krakauer, David, editor, Tranquillo, Robert T., editor, Anderson, Alexander R. A., editor, Chaplain, Mark A. J., editor, and Rejniak, Katarzyna A., editor

Published
2007
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17. Multiscale Models for Vertebrate Limb Development

Author

Newman, Stuart A., primary, Christley, Scott, additional, Glimm, Tilmann, additional, Hentschel, H.G.E., additional, Kazmierczak, Bogdan, additional, Zhang, Yong-Tao, additional, Zhu, Jianfeng, additional, and Alber, Mark, additional

Published
2008
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27. Additional file 2: Figure S2. of Deep phylogenomics of a tandem-repeat galectin regulating appendicular skeletal pattern formation

Author

Ramray Bhat, Mahul Chakraborty, Glimm, Tilmann, Stewart, Thomas, and Newman, Stuart

Abstract

Figure showing greater overall amino acid residue conservation (in comparison with the primary structure of C. milii Gal-8) within sarcopterygian Gal-8 relative to actinopterygian Gal-8. Residues within pre-N-CRD region, N- and C-CRDs of Gal-8 are conserved to a greater extent within Sarcopterygii (digits within brackets represent highly conserved residues, whereas digits without brackets represent residues with strong as well as weak conservation: see Materials and Methods for definitions for the criteria of strong and weak conservation). (PDF 64 kb)

Published
2016
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42. Two-dimensional Multiscale Model of Cell Motion in a Chemotactic Field.

Author

Alt, Wolfgang, Adler, Fred, Chaplain, Mark, Deutsch, Andreas, Dress, Andreas, Krakauer, David, Tranquillo, Robert T., Anderson, Alexander R. A., Chaplain, Mark A. J., Rejniak, Katarzyna A., Alber, Mark, Nan Chen, Glimm, Tilmann, and Lushnikov, Pavel

Abstract

The Cellular Potts Model (CPM) has been used at a cellular scale for simulating various biological phenomena such as differential adhesion, fruiting body formation of the slime mold Dictyostelium discoideum, angiogenesis, cancer invasion, chondrogenesis in embryonic vertebrate limbs, and many others. Continuous models in the form of partial differential, integral or integro-differential equations are used for studying biological problems at large scale. It is crucial for developing multiscale biological models to establish a connection between discrete microscopic stochastic models, including CPM, and macroscopic continuous models. To demonstrate multiscale approach we derive in this paper continuous limit of a two-dimensional CPM with the chemotactic interactions in the form of a Fokker-Planck equation describing evolution of the cell probability density function. This equation is then reduced to the classical macroscopic Keller-Segel model. We demonstrate that CPM Monte Carlo simulations are in excellent agreement with the numerics for the continuous macroscopic model with different forms of the chemical field term. [ABSTRACT FROM AUTHOR]

Published
2007
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43. Stability of n-dimensional patterns in a generalized Turing system: implications for biological pattern formation

Author

Alber, Mark, Glimm, Tilmann, Hentschel, H G E, Kazmierczak, Bogdan, and Newman, Stuart A

Abstract

The stability of Turing patterns in an n-dimensional cube (0, π)n is studied, where n ≥ 2. It is shown by using a generalization of a classical result of Ermentrout concerning spots and stripes in two dimensions that under appropriate assumptions only sheet-like or nodule-like structures can be stable in an n-dimensional cube. Other patterns can also be stable in regions comprising products of lower-dimensional cubes and intervals of appropriate length. Stability results are applied to a new model of skeletal pattern formation in the vertebrate limb.

Published
2005

44. Multiscale Models for Vertebrate Limb Development.

Author

Newman, Stuart A., Christley, Scott, Glimm, Tilmann, Hentschel, H. G. E., Kazmierczak, Bogdan, Yong-Tao Zhang, Jianfeng Zhu, and Alber, Mark

Subjects
VERTEBRATE embryology
Abstract

An abstract of the article "Multiscale Models for Vertebrate Limb Development," by Stuart A. Newman and colleagues is presented.

Published
2007
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45. The senescent mesothelial matrix accentuates colonization by ovarian cancer cells.

Author

Thapa BV, Banerjee M, Glimm T, Saini DK, and Bhat R

Subjects
Female, Animals, Humans, Mice, Epithelium, Peritoneum pathology, Extracellular Matrix, Cell Adhesion physiology, Fibronectins, Ovarian Neoplasms pathology
Abstract

Ovarian cancer is amongst the most morbid of gynecological malignancies due to its diagnosis at an advanced stage, a transcoelomic mode of metastasis, and rapid transition to chemotherapeutic resistance. Like all other malignancies, the progression of ovarian cancer may be interpreted as an emergent outcome of the conflict between metastasizing cancer cells and the natural defense mounted by microenvironmental barriers to such migration. Here, we asked whether senescence in coelom-lining mesothelia, brought about by drug exposure, affects their interaction with disseminated ovarian cancer cells. We observed that cancer cells adhered faster on senescent human and murine mesothelial monolayers than on non-senescent controls. Time-lapse epifluorescence microscopy showed that mesothelial cells were cleared by a host of cancer cells that surrounded the former, even under sub-confluent conditions. A multiscale computational model predicted that such colocalized mesothelial clearance under sub-confluence requires greater adhesion between cancer cells and senescent mesothelia. Consistent with the prediction, we observed that senescent mesothelia expressed an extracellular matrix with higher levels of fibronectin, laminins and hyaluronan than non-senescent controls. On senescent matrix, cancer cells adhered more efficiently, spread better, and moved faster and persistently, aiding the spread of cancer. Inhibition assays using RGD cyclopeptides suggested the adhesion was predominantly contributed by fibronectin and laminin. These findings led us to propose that the senescence-associated matrisomal phenotype of peritoneal barriers enhances the colonization of invading ovarian cancer cells contributing to the metastatic burden associated with the disease., (© 2023. The Author(s).)

Published
2023
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46. Multiscale modeling of vertebrate limb development.

Author

Glimm T, Bhat R, and Newman SA

Subjects
Animals, Biological Evolution, Extremities physiology, Organogenesis, Vertebrates growth & development, Extremities growth & development, Models, Biological
Abstract

We review the current state of mathematical modeling of cartilage pattern formation in vertebrate limbs. We place emphasis on several reaction-diffusion type models that have been proposed in the last few years. These models are grounded in more detailed knowledge of the relevant regulatory processes than previous ones but generally refer to different molecular aspects of these processes. Considering these models in light of comparative phylogenomics permits framing of hypotheses on the evolutionary order of appearance of the respective mechanisms and their roles in the fin-to-limb transition. This article is categorized under: Analytical and Computational Methods > Computational Methods Models of Systems Properties and Processes > Mechanistic Models Developmental Biology > Developmental Processes in Health and Disease Analytical and Computational Methods > Analytical Methods., (© 2020 Wiley Periodicals, Inc.)

Published
2020
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47. Multiscale models for vertebrate limb development.

Author

Newman SA, Christley S, Glimm T, Hentschel HG, Kazmierczak B, Zhang YT, Zhu J, and Alber M

Subjects
Animals, Body Patterning, Chondrogenesis, Gene Expression Regulation, Developmental, Growth Substances genetics, Growth Substances physiology, Morphogenesis, Stochastic Processes, Systems Biology, Vertebrates genetics, Vertebrates growth & development, Extremities growth & development, Models, Biological
Abstract

Dynamical systems in which geometrically extended model cells produce and interact with diffusible (morphogen) and nondiffusible (extracellular matrix) chemical fields have proved very useful as models for developmental processes. The embryonic vertebrate limb is an apt system for such mathematical and computational modeling since it has been the subject of hundreds of experimental studies, and its normal and variant morphologies and spatiotemporal organization of expressed genes are well known. Because of its stereotypical proximodistally generated increase in the number of parallel skeletal elements, the limb lends itself to being modeled by Turing-type systems which are capable of producing periodic, or quasiperiodic, arrangements of spot- and stripe-like elements. This chapter describes several such models, including, (i) a system of partial differential equations in which changing cell density enters into the dynamics explicitly, (ii) a model for morphogen dynamics alone, derived from the latter system in the "morphostatic limit" where cell movement relaxes on a much slower time-scale than cell differentiation, (iii) a discrete stochastic model for the simplified pattern formation that occurs when limb cells are placed in planar culture, and (iv) several hybrid models in which continuum morphogen systems interact with cells represented as energy-minimizing mesoscopic entities. Progress in devising computational methods for handling 3D, multiscale, multimodel simulations of organogenesis is discussed, as well as for simulating reaction-diffusion dynamics in domains of irregular shape.

Published
2008
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48. A framework for three-dimensional simulation of morphogenesis.

Author

Cickovski TM, Huang C, Chaturvedi R, Glimm T, Hentschel HG, Alber MS, Glazier JA, Newman SA, and Izaguirre JA

Subjects
Animals, Cell Physiological Phenomena, Chick Embryo, Chickens, Chondrogenesis, Computing Methodologies, Database Management Systems, Energy Metabolism, Forelimb cytology, Forelimb embryology, Forelimb physiology, Programming Languages, User-Computer Interface, Computer Simulation, Models, Biological, Morphogenesis
Abstract

We present COMPUCELL3D, a software framework for three-dimensional simulation of morphogenesis in different organisms. COMPUCELL3D employs biologically relevant models for cell clustering, growth, and interaction with chemical fields. COMPUCELL3D uses design patterns for speed, efficient memory management, extensibility, and flexibility to allow an almost unlimited variety of simulations. We have verified COMPUCELL3D by building a model of growth and skeletal pattern formation in the avian (chicken) limb bud. Binaries and source code are available, along with documentation and input files for sample simulations, at http:// compucell.sourceforge.net.

Published
2005
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49. Dynamical mechanisms for skeletal pattern formation in the vertebrate limb.

Author

Hentschel HG, Glimm T, Glazier JA, and Newman SA

Subjects
Animals, Cartilage cytology, Cartilage embryology, Cell Adhesion physiology, Cell Differentiation physiology, Fibroblast Growth Factors metabolism, Fibronectins metabolism, Mesoderm physiology, Receptors, Fibroblast Growth Factor metabolism, Transforming Growth Factor beta metabolism, Body Patterning physiology, Chondrogenesis physiology, Extremities embryology, Models, Biological, Vertebrates embryology
Abstract

We describe a 'reactor-diffusion' mechanism for precartilage condensation based on recent experiments on chondrogenesis in the early vertebrate limb and additional hypotheses. Cellular differentiation of mesenchymal cells into subtypes with different fibroblast growth factor (FGF) receptors occurs in the presence of spatio-temporal variations of FGFs and transforming growth factor-betas (TGF-betas). One class of differentiated cells produces elevated quantities of the extracellular matrix protein fibronectin, which initiates adhesion-mediated preskeletal mesenchymal condensation. The same class of cells also produces an FGF-dependent laterally acting inhibitor that keeps condensations from expanding beyond a critical size. We show that this 'reactor-diffusion' mechanism leads naturally to patterning consistent with skeletal form, and describe simulations of spatio-temporal distribution of these differentiated cell types and the TGF-beta and inhibitor concentrations in the developing limb bud.

Published
2004
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