Identifying distinct nanoscopic features of native collagen fibrils towards early diagnosis of pelvic organ prolapse.

Unlabelled: Pelvic organ prolapse (POP) is characterized by weakening of the connective tissues and loss of support for the pelvic organs. Collagen is the predominant, load-bearing protein within pelvic floor connective tissues. In this study, we examined the nanoscopic structures and biomechanics of native collagen fibrils in surgical, vaginal wall connective tissues from healthy women and POP patients.

Effect of CNT on collagen fiber structure, stiffness assembly kinetics and stem cell differentiation.

Collagen is a native one-dimensional nanomaterial. Carbon nanotube (CNT) was found to interface with biological materials and show promising applications in creating reinforced scaffolds for tissue engineering and regenerative medicine. In this study, we examined the unique role of CNT in collagen fiber structure, mechanical strength and assembly kinetics.

Matrix-specified differentiation of human decidua parietalis placental stem cells.

To create suitable biological scaffolds for tissue engineering and cell therapeutics, it is essential to understand the matrix-mediated specification of stem cell differentiation. To this end, we studied the effect of collagen type I on stem cell lineage specification. We altered the properties of collagen type I by incorporating carbon nanotubes (CNT).

Structural and mechanical profiles of native collagen fibers in vaginal wall connective tissues.

Collagen, an ubiquitous biomaterial, confers robustness and resilience to connective tissues. In this study, we analyzed the structure and elasticity profile of collagen from the vaginal wall connective tissue of healthy pre-menopausal (pre-M) and postmenopausal (post-M) women. The histological staining assisted study with an atomic force microscope renders the examination of native collagen fibers on site of the connective tissue from nanoscopic scale to microscopic scale with high spatial resolution.

Analysis of affinity maps of membrane proteins on individual human embryonic stem cells.

The heterogeneity found in many cell types has greatly inspired research in single-cell gene and protein profiling for discovering the origin of heterogeneity and its role in cell fate decisions. Among the existing techniques to probe heterogeneity, atomic force microscopy (AFM) utilizes an antibody/ligand-modified tip to explore the distribution of a target membrane protein on individual cells in their native environment. In this paper, we establish a practical model to analyze the data systematically, and attempt the quantification of membrane protein abundance on single cells by taking account issues, such as the level of nonspecific interaction, the probe resolution, and the reproducibility of detecting protein distribution.

Spatially resolved quantification of E-cadherin on target hES cells.

The local expression and distribution pattern of protein on a cell play essential roles in signal transduction within a cell or between cells. Here we report on the development of a spatially resolved quantification method, which was applied in the study of E-cadherin local expression in identified undifferentiated and differentiated human embryonic stem (hES) cells in their native cellular environment. This was achieved by a novel immunofluorescence assisted affinity mapping (IF-AM) method, in which immunofluorescence provides the guidance to locate a desired type of cell in a cell community for performing affinity mapping to quantify the local protein density.

Adapting collagen/CNT matrix in directing hESC differentiation.

The lineage selection in human embryonic stem cell (hESC) differentiation relies on both the growth factors and small molecules in the media and the physical characteristics of the micro-environment. In this work, we utilized various materials, including the collagen-carbon nanotube (collagen/CNT) composite material, as cell culture matrices to examine the impact of matrix properties on hESC differentiation. Our AFM analysis indicated that the collagen/CNT formed rigid fibril bundles, which polarized the growth and differentiation of hESCs, resulting in more than 90% of the cells to the ectodermal lineage in Day 3 in the media commonly used for spontaneous differentiation.