Dynamic Properties of Heart Fragments from Different Regions and Their Synchronization.

The dynamic properties of the heart differ based on the regions that effectively circulate blood throughout the body with each heartbeat. These properties, including the inter-beat interval (IBI) of autonomous beat activity, are retained even in in vitro tissue fragments. However, details of beat dynamics have not been well analyzed, particularly at the sub-mm scale, although such dynamics of size are important for regenerative medicine and computational studies of the heart. We analyzed the beat dynamics in sub-mm tissue fragments from atria and ventricles of hearts obtained from chick embryos over a period of 40 h. The IBI and contraction speed differed by region and atrial fragments retained their values for a longer time. The major finding of this study is synchronization of these fragment pairs physically attached to each other. The probability of achieving this and the time required differ for regional pairs: atrium-atrium, ventricle-ventricle, or atrium-ventricle. Furthermore, the time required to achieve 1:1 synchronization does not depend on the proximity of initial IBI of paired fragments. Various interesting phenomena, such as 1:n synchronization and a reentrant-like beat sequence, are revealed during synchronization. Finally, our observation of fragment dynamics indicates that mechanical motion itself contributes to the synchronization of atria.

Biochemical study of type I collagen purified from skin of warm sea teleost Mahi mahi (Coryphaena hippurus), with a focus on thermal and physical stability.

Acid- and pepsin-soluble collagen were purified from the skin of mahi mahi (mmASC and mmPSC). The Pro+Hyp content of the latter (185/1,000 residues) was highest among all marine teleost fishes. Fourier transform infrared spectroscopy and Circular Dichroism (CD) analysis showed the typical structure of type I collagen. The ratio of positive over negative peak intensity calculated from the CD spectrum was approximately 1.19 in mmPSC, which is remarkably high, and indicates the stability of the triple helix. The denaturation temperatures (Td ) of mmASC and mmPSC were the highest (29.5 and 28.8°C, respectively) among the marine teleost fishes previously studied. atomic force microscope and scanning electron microscope images showed that even after pretreatment, the fibrils presented their structure and fiber orientation. These results indicate the robustness of both collagens, which can be attributed to the high value of Pro+Hyp stabilizing the helix structure of the collagen molecule. Practical applications While Mahi mahi is highly valuable for its meat, other parts such as skin is not fully utilized in seafood industry. On the contrary, it has been empirically shown that the skin of Mahi mahi has high thermal stability, thus, the skin has been used for leather products in some areas located in the tropical and subtropical zones. In this study, we focused on collagen a major component in skin and investigated the structure and the biochemical characteristics of it. Some results showed that collagen from skin has high physical stability. The collagen from skin of Mahi mahi will be a new fishery resource which could be used as a material for collagen products.

Clog and Release, and Reverse Motions of DNA in a Nanopore.

Motions of circular and linear DNA molecules of various lengths near a nanopore of 100 or 200 nm diameter were experimentally observed and investigated by fluorescence microscopy. The movement of DNA molecules through nanopores, known as translocation, is mainly driven by electric fields near and inside the pores. We found significant clogging of nanopores by DNA molecules, particularly by circular DNA and linear T4 DNA (165.65 kbp). Here, the probabilities of DNA clogging events, depending on the DNA length and shape-linear or circular-were determined. Furthermore, two distinct DNA motions were observed: clog and release by linear T4 DNA, and a reverse direction motion at the pore entrance by circular DNA, after which both molecules moved away from the pore. Finite element method-based numerical simulations were performed. The results indicated that DNA molecules with pores 100⁻200 nm in diameter were strongly influenced by opposing hydrodynamic streaming flow, which was further enhanced by bulky DNA configurations.