Add to ORKGA new material model is proposed for the description of stress-softening observed in cyclic tension tests performed on soft biological tissues. The modeling framework is based on the concept of internal variables introducing a scalar-valued variable for the representation of fiber damage. Remanent strains in fiber direction can be represented as a result of microscopic damage of the fiber crosslinks. Particular internal variables are defined able to capture the nature of soft biological tissues that no damage occurs in the physiological loading domain. A specific model is adjusted to experimental data taking into account the supra-physiological loading regime. For the description of the physiological domain polyconvex functions are used which al...
We propose a mechanical model to account for progressive damage in collagen fibres within fibrous so...
An idealized model of an arterial wall is proposed as a two-layer system. Distinct mechanical respon...
Living biological tissues are complex structures that have the capacity of evolving in response to e...
A new material model is proposed for the description of stress-softening observed in cyclic tension ...
This paper deals with the formulation of a micro-mechanically based dam-age model for soft collageno...
AbstractDeformation induced softening is an inelastic phenomenon frequently accompanying mechanical ...
Tissue overload during medical procedures can lead to severe complications. This chapter presents an...
This chapter provides a detailed summary of the background from the nonlinear theory of continuum me...
This doctoral thesis deals with the description of the mechanical behavior of arterial walls under s...
Soft biological tissues show a strongly non linear and time-dependent mechanical response and underg...
Damage to soft tissues in the human body has been investigated for applications in healthcare, sport...
AbstractThis paper presents a comparison between deterministic and stochastically based three-dimens...
Enormous progress has been made during recent years in the phenomenological modelling of soft tissue...
Healing in soft biological tissues is a chain of events on different time and length scales. This wo...
The present experimental-modelling study provides a quantitative interpretation of mechanical data a...
We propose a mechanical model to account for progressive damage in collagen fibres within fibrous so...
An idealized model of an arterial wall is proposed as a two-layer system. Distinct mechanical respon...
Living biological tissues are complex structures that have the capacity of evolving in response to e...
A new material model is proposed for the description of stress-softening observed in cyclic tension ...
This paper deals with the formulation of a micro-mechanically based dam-age model for soft collageno...
AbstractDeformation induced softening is an inelastic phenomenon frequently accompanying mechanical ...
Tissue overload during medical procedures can lead to severe complications. This chapter presents an...
This chapter provides a detailed summary of the background from the nonlinear theory of continuum me...
This doctoral thesis deals with the description of the mechanical behavior of arterial walls under s...
Soft biological tissues show a strongly non linear and time-dependent mechanical response and underg...
Damage to soft tissues in the human body has been investigated for applications in healthcare, sport...
AbstractThis paper presents a comparison between deterministic and stochastically based three-dimens...
Enormous progress has been made during recent years in the phenomenological modelling of soft tissue...
Healing in soft biological tissues is a chain of events on different time and length scales. This wo...
The present experimental-modelling study provides a quantitative interpretation of mechanical data a...
We propose a mechanical model to account for progressive damage in collagen fibres within fibrous so...
An idealized model of an arterial wall is proposed as a two-layer system. Distinct mechanical respon...
Living biological tissues are complex structures that have the capacity of evolving in response to e...