ABSTRACT
Since smart phones have been developed, significant advances in the function of mobile phone due to the development of software, hardware and accessories have been reached. Till now, smart phones have been engaged in daily life with an increasing impact. As a new medical model, mobile phone medicine is emerging and has found wide spread applications in medicine, especially in diagnosing, monitoring and screening various diseases. In addition, mo bile phone medical application shows great potential trend to improve healthcare in resource-limited regions due to its advantageous features of portability and information communication capability. Nowadays, the scientific and technological issues related to mobile phone medicine have attracted worldwide attention. In this review, we summarize state-of-the-art advances of mobile phone medicine with focus on its diagnostics applications in order to expand the fields of their applications and promote healthcare informatization.
Subject(s)
Humans , Cell Phone , Delivery of Health Care , SoftwareABSTRACT
To develop standard in vitro chondrosarcoma models, we synthesized three hydrogels (i. e., PDMAAm, PNaAMPS and PMETAC) and investigated the influence of Young's modulus, swelling ratio and electric charges on the behavior of chondrosarcoma cells seeded on the hydrogels, including morphology, adhesion and aggregation. Results showed that the morphology of chondrosarcoma cells at 6h was dependent on the charges of hydrogels; cells present spindle-shaped and round-shaped morphology on negative charged and neutral hydrogel, respectively, while no cells spreaded on positive charged hydrogel. Chondrosarcoma cells formed aggregates on neutral PDMAAm after further culture. The hydrogels can be synthesized easily and has the characteristics of ease at use with defined components, which holds great potential for developing standard chondrosarcoma models in vitro.
Subject(s)
Humans , Bone Neoplasms , Pathology , Cell Line, Tumor , Cell Proliferation , Chondrosarcoma , Pathology , Hydrogels , Chemistry , Pharmacology , Methacrylates , Pharmacology , Nylons , Pharmacology , Static ElectricityABSTRACT
Skin thermal damage or skin burns are the most commonly encountered type of trauma in civilian and military communities. Besides, advances in laser, microwave and similar technologies have led to recent developments of thermal treatments for disease and damage involving skin tissue, where the objective is to induce thermal damage precisely within targeted tissue structures but without affecting the surrounding, healthy tissue. Further, extended pain sensation induced by thermal damage has also brought great problem for burn patients. Thus, it is of great importance to quantify the thermal damage in skin tissue. In this paper, the available models and experimental methods for quantification of thermal damage in skin tissue are discussed.
ABSTRACT
Objective To test the hypothesis that collagen is a significant determinant of skin viscoelasticity,with particular attention paid to the thermomechanical properties of skin under dynamic loading.Methods Differential scanning calorimetry (DSC) was used to detect the denaturation of dermal collagen and assess its thermal stability.The DSC results obtained with various heating rates were used to derive the Arrhenius parameters in burn damage integration,which were subsequently used to calculate the degree of denatured collagen in the skin.The dynamic mechanical analyzer (DMA) was employed to evaluate the changes in skin viscoelastic properties as a function of temperature and collagen damage.Results The results showed remarkable changes in storage modulus,possibly due to the release of water,whilst there was no significant change in loss factor.Conclusion These results suggest that at a fixed frequency the denaturation of collagen molecules has a large effect on the viscoelastic behavior of skin tissue.
ABSTRACT
Objective This paper aims to characterize the tensile and compressive behaviors of skin tissue under different temperatures and to study the effect of temperature and corresponding dermal collagen denaturation on the mechanical properties of skin tissue.Methods The uniaxial tensile and compressive tests of fresh pig ear skin under different temperatures have been performed by using two specifically-designed hydrothermal experimental systems.Results In tensile tests,the skin stiffness decreases with increased temperature,while a contrary trend is observed in compressive tests.Conclusion The results show that temperature has a great influence on both tensile and compressive properties of skin tissue,but the mechanisms are different.The variation of skin tensile properties is caused by the thermal denaturation of skin collagen with increased temperature,while the variation of skin compressive behavior of skin tissue may be due to the hydration change with thermal denaturation.
ABSTRACT
Objective The aim of this paper is to develop a holistic mathematical model to quantify the correlation between skin thermal sensation and noxious stimuli,since skin thermal pain is one of the most common problems in everyday life and the understanding of the underlying physical mechanisms is still not clear.Methods The model is developed by considering the biothermomechanical behaviour of skin tissue and by incorporating the current understanding of biophysical and neurophysiological mechanisms of pain sensation.Results The proposed model consisted of three interconnected sub-models: peripheral modulation of noxious stimuli,which converts the energy from a noxious thermal stimulus into electrical energy via nerve impulses;transmission,which transports these neural signals from the site of transduction in the skin to the spinal cord and brain;and modulation and perception in the spinal cord and brain.The model predictions agree well with existing experimental data.Conclusion With this model,a direct relationship has been built between the level of thermal pain sensation and the character of noxious stimuli.