The female reproductive system consists of the ovaries,the female gonads,and the reproductive tract organs of the fallopian tubes,uterus,cervix,and vagina.It functions to provide hormonal support and anatomical struct...The female reproductive system consists of the ovaries,the female gonads,and the reproductive tract organs of the fallopian tubes,uterus,cervix,and vagina.It functions to provide hormonal support and anatomical structure for the production of new offspring.A number of endogenous and exogenous factors can impact female reproductive health and fertility,including genetic vulnerability,medications,environmental exposures,age,nutrition,and diseases.To date,due to the ethical concerns of using human subjects in biomedical research,the majority of studies use in vivo animal models and 2D cell/tissue culture models to study female reproduction.However,the complexity and species difference of the female reproductive system in humans make it difficult to compare to those of animals.Moreover,the monolayered cells cultured on flat plastics or glass lose their 3D architecture as well as the physical and/or biochemical contacts with other cells in vivo.Further,all reproductive organs do not work alone but interconnect with each other and also with non-reproductive organs to support female reproductive,endocrine,and systemic health.These facts suggest that there is an urgent and unmet need to develop representative,effective,and efficient in vitro models for studying human female reproduction.The prodigious advancements of bioengineering(e.g.,biomaterials,3D printing,and organ-on-a-chip)allow us to study female reproduction in an entirely new way.Here,we review recent advances that use bioengineering methods to study female reproduction,including the bioengineering models of the ovary,fallopian tube,uterus,embryo implantation,placenta,and reproductive disease.展开更多
3D audio effects can provide immersive auditory experience, but we often face the so-called in-head localization (IHL) problem in headphone sound reproduction. To ad- dress this problem, we propose an effective soun...3D audio effects can provide immersive auditory experience, but we often face the so-called in-head localization (IHL) problem in headphone sound reproduction. To ad- dress this problem, we propose an effective sound image externalization approach. Specifically, we consider several important factors related to sound propagation, which include image-source model based early reflections with distance decay, wall absorption and air absorption, late reverberation and other dynamic factors like head movement. We apply our sound image externalization approach to a headphone based real-time 3D audio system. Subjective listening tests show that the sound image externalization performance is significantly improved and the sound source direction is preserved as well. A/B preference test further shows that, as compared with a recent popular approach, the proposed approach is mostly preferred by the listeners.展开更多
基金This work is supported by the National Institutes of Health(NIH K01ES030014 and P01ES028942)National Science Foundation(NSF 183291)。
文摘The female reproductive system consists of the ovaries,the female gonads,and the reproductive tract organs of the fallopian tubes,uterus,cervix,and vagina.It functions to provide hormonal support and anatomical structure for the production of new offspring.A number of endogenous and exogenous factors can impact female reproductive health and fertility,including genetic vulnerability,medications,environmental exposures,age,nutrition,and diseases.To date,due to the ethical concerns of using human subjects in biomedical research,the majority of studies use in vivo animal models and 2D cell/tissue culture models to study female reproduction.However,the complexity and species difference of the female reproductive system in humans make it difficult to compare to those of animals.Moreover,the monolayered cells cultured on flat plastics or glass lose their 3D architecture as well as the physical and/or biochemical contacts with other cells in vivo.Further,all reproductive organs do not work alone but interconnect with each other and also with non-reproductive organs to support female reproductive,endocrine,and systemic health.These facts suggest that there is an urgent and unmet need to develop representative,effective,and efficient in vitro models for studying human female reproduction.The prodigious advancements of bioengineering(e.g.,biomaterials,3D printing,and organ-on-a-chip)allow us to study female reproduction in an entirely new way.Here,we review recent advances that use bioengineering methods to study female reproduction,including the bioengineering models of the ovary,fallopian tube,uterus,embryo implantation,placenta,and reproductive disease.
文摘3D audio effects can provide immersive auditory experience, but we often face the so-called in-head localization (IHL) problem in headphone sound reproduction. To ad- dress this problem, we propose an effective sound image externalization approach. Specifically, we consider several important factors related to sound propagation, which include image-source model based early reflections with distance decay, wall absorption and air absorption, late reverberation and other dynamic factors like head movement. We apply our sound image externalization approach to a headphone based real-time 3D audio system. Subjective listening tests show that the sound image externalization performance is significantly improved and the sound source direction is preserved as well. A/B preference test further shows that, as compared with a recent popular approach, the proposed approach is mostly preferred by the listeners.