Influence of high-frequency cyclical stimulation on the bone fracture-healing process: mathematical and experimental models

Gómez‐Benito, María José; Torres, Libardo Andrés González; Reina-Romo, Esther; Grasa, J.; Seral, B.; García-Aznar, J.M.

doi:10.1098/rsta.2011.0153

Cited by 21 publications

(18 citation statements)

References 69 publications

(117 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In a study developed by González‐Torres et al. , a finite‐element model of a sheep tibia metatarsus fracture allowed the conclusion that the change in the frequency of the external mechanical stimulus directly affects the interstitial fluid flow velocity in the fracture callus. Goodship et al .…”

Section: Current Biomechanical Nail Improvements and Upgradesmentioning

confidence: 99%

“…37,38 However, very recent studies [38][39][40] have started to demonstrate the positive correlation that underestimated high-frequency, low-magnitude interfragmentary micromotions have on the rate and quality of bone fracture healing. According to Gómez-Benito et al, 41 these stimuli may be associated with the promotion of endochondral ossification and an increase in the rate of cell proliferation and tissue synthesis. Although several studies support this concept, it has not yet been fully clarified.…”

Section: Current Biomechanical Nail Improvements and Upgradesmentioning

confidence: 99%

“…The importance of frequency value in the mechanical stimulus was also considered. In a study developed by González-Torres et al, 41 a finite-element model of a sheep tibia metatarsus fracture allowed the conclusion that the change in the frequency of the external mechanical stimulus directly affects the interstitial fluid flow velocity in the fracture callus. Goodship et al 38 reinforced the idea that mechanical stimuli do not need to be large to positively influence the fracture-healing process.…”

Section: Current Biomechanical Nail Improvements and Upgradesmentioning

confidence: 99%

See 2 more Smart Citations

Recent developments on intramedullary nailing: a biomechanical perspective

Rosa

Marta

Vaz

et al. 2017

Annals of the New York Academy of Sciences

View full text Add to dashboard Cite

Combining contributions from engineering and medicine, we highlight the biomechanical turning points in the historical evolution of the intramedullary nailing stabilization technique and discuss the recent innovations concerning increase in bone-implant system stability. Following the earliest attempts, where stabilization of long bone fractures was purely based on intuition, intramedullary nailing evolved from allowing alignment and translational control through press-fit fixation to current clinical widespread acceptance marked by the mechanical linkage between nail and bone with interlocking screws that allow alignment, translation, rotation, and length control. In an attempt to achieve an optimum interfragmentary mechanical environment, recent improvements considered the impact of different biomaterials on bone-implant stiffness. Another strategy considered the increase in the structural stability through the reduction of the number of movements between the different components that constitute the bone-implant system. Intramedullary nail improvements will most likely benefit from merging mechanics and fracture-healing biology by combining surface engineering with sensor tools associated with the innovative progress in wireless technology and with bone-healing biological active agents. Future research should aim at better understanding the ideal mechanobiological environment for each stage of fracture healing in order to allow for intramedullary nail design that satisfies such requirements.

show abstract

Section: Current Biomechanical Nail Improvements and Upgradesmentioning

confidence: 99%

Section: Current Biomechanical Nail Improvements and Upgradesmentioning

confidence: 99%

Section: Current Biomechanical Nail Improvements and Upgradesmentioning

confidence: 99%

See 1 more Smart Citation

Recent developments on intramedullary nailing: a biomechanical perspective

Rosa

Marta

Vaz

et al. 2017

Annals of the New York Academy of Sciences

View full text Add to dashboard Cite

show abstract

“…On the other hand, the use of in silico models offers a wide (and cheap) spectrum for analyses. Consequently, it is called to play a prominent role in the design of new treatments, due to its intrinsic capacity to isolate single factors [18].…”

Section: Introductionmentioning

confidence: 99%

Computational Modelling of Wound Healing Insights to Develop New Treatments

Gómez‐Benito

Valero

García-Aznar

et al. 2019

New Developments in Tissue Engineering and Regeneration

View full text Add to dashboard Cite

About 1% of the population will suffer a severe wound during their life. Thus, it is really important to develop new techniques in order to properly treat these injuries due to the high socioeconomically impact they suppose. Skin substitutes and pressure based therapies are currently the most promising techniques to heal these injuries. Nevertheless, we are still far from finding a definitive skin substitute for the treatment of all chronic wounds. As a first step in developing new tissue engineering tools and treatment techniques for wound healing, in silico models could help in understanding the mechanisms and factors implicated in wound healing. Here, we review mathematical models of wound healing. These models include different tissue and cell types involved in healing, as well as biochemical and mechanical factors which determine this process. Special attention is paid to the contraction mechanism of cells as an answer to the tissue mechanical state. Other cell processes such as differentiation and proliferation are also included in the models together with extracellular matrix production. The results obtained show the dependency of the success of wound healing on tissue composition and the importance of the different biomechanical and biochemical factors. This could help to individuate the adequate concentration of growth factors to accelerate healing and also the best mechanical properties of the new skin substitute depending on the wound location in the body and

show abstract

“…Burrowes et al [12] demonstrate, via computational simulation of patient-derived vascular occlusions in a model of the pulmonary circulation, that mechanical obstruction alone is not sufficient to cause pulmonary arterial hypertension, additional downstream occlusion being needed to increase pressures significantly. The study by Gómez-Benito et al [13] is aimed at determining the influence of high-frequency, low-amplitude cyclical stimulation on the bonehealing process. Combining experiments and predictions of a previously published mechano-biological model, the authors propose the design of a new bone-healing treatment.…”

mentioning

confidence: 99%

Towards the virtual physiological human: mathematical and computational case studies

Brook

Kohl

King

2011

Phil. Trans. R. Soc. A.

View full text Add to dashboard Cite

PREFACE Towards the virtual physiological human: mathematical and computational case studiesUntil recently, much of the investigative effort in the life sciences has been datagathering orientated, the 'genetic revolution' being an exemplary case. It has become clear in recent years that (i) this data-driven science is not sufficient to understand the function of the incredibly complex biology of interactions from molecular-level to organ-level processes within the human body and (ii) a purely statistical (or evidence based) understanding of health-and disease-related data is not going to allow one fully to apply insight to an individual patient. The virtual physiological human (VPH) initiative is a direction in computational biomedicine that aims to develop a thoroughly data-based framework of methods and technologies that will facilitate the understanding of integrative function from sub-cellular structures, through cells and organs, to the human body as a whole [1]. Many of the methods and technologies needed for this endeavour are model-driven approaches to prediction that have long been used in the physical sciences. Building upon international physiome activities [2], the Strategy for the EuroPhysiome (STEP) project [3] developed a research roadmap that conceived the VPH concept. This roadmap identified the need to break down barriers between life scientists, physical scientists and medical practitioners to enable the fully integrative approach necessary for tackling the challenges that lie ahead.Since long before the STEP project, attempts to overcome such barriers have included the Mathematics in Medicine Study Groups.1 These annual workshops continue to bring together biologists and mathematicians with the aim of developing mathematical models that address very specific biology-or healthrelated questions. Researchers from experimental and industrial laboratories are invited to present technical problems for study in working sessions with leading mathematicians from the academic community. In a week of brainstorming and mathematical modelling, which involves significant communication between the disciplines, there is usually enough time to generate and assess many ideas for solving the problem. A significant number of interdisciplinary collaborations have stemmed from and been fostered by such activities; examples include models for cyst growth [4], cell signalling and differentiation [5], glaucoma [6] and placental transport [7]. Study groups were identified by the VPH community as a useful 1 Mathematics in Medicine website: http://www.maths-in-medicine.org.One contribution of 11 to a Theme Issue 'Towards the virtual physiological human: mathematical and computational case studies'.This journal is

show abstract

Influence of high-frequency cyclical stimulation on the bone fracture-healing process: mathematical and experimental models

Cited by 21 publications

References 69 publications

Recent developments on intramedullary nailing: a biomechanical perspective

Recent developments on intramedullary nailing: a biomechanical perspective

Computational Modelling of Wound Healing Insights to Develop New Treatments

Towards the virtual physiological human: mathematical and computational case studies

Contact Info

Product

Resources

About