Long-term and non-invasive in vivo tracking of DiD dye-labeled human hepatic progenitors in chronic liver disease models.

BACKGROUND: Chronic liver diseases (CLD) are the major public health burden due to the continuous increasing rate of global morbidity and mortality. The inherent limitations of organ transplantation have led to the development of stem cell-based therapy as a supportive and promising therapeutic option. However, identifying the fate of transplanted cells in vivo represents a crucial obstacle. AIM: To evaluate the potential applicability of DiD dye as a cell labeling agent for long-term, and non-invasive in vivo tracking of transplanted cells in the liver. METHODS: Magnetically sorted, epithelial cell adhesion molecule positive (1 × 106 cells/mL) fetal hepatic progenitor cells were labeled with DiD dye and transplanted into the livers of CLD-severe combined immunodeficiency (SCID) mice. Near-infrared (NIR) imaging was performed for in vivo tracking of the DiD-labeled transplanted cells along with colocalization of hepatic markers for up to 80 d. The existence of human cells within mouse livers was identified using Alu polymerase chain reaction and sequencing. RESULTS: NIR fluorescence imaging of CLD-SCID mice showed a positive fluorescence signal of DiD at days 7, 15, 30, 45, 60, and 80 post-transplantation. Furthermore, positive staining of cytokeratin, c-Met, and albumin colocalizing with DiD fluorescence clearly demonstrated that the fluorescent signal of hepatic markers emerged from the DiD-labeled transplanted cells. Recovery of liver function was also observed with serum levels of glutamic-oxaloacetic transaminase, glutamate-pyruvate transaminase, and bilirubin. The detection of human-specific Alu sequence from the transplanted mouse livers provided evidence for the survival of transplanted cells at day 80. CONCLUSION: DiD-labeling is promising for long-term and non-invasive in vivo cell tracking, and understanding the regenerative mechanisms incurred by the transplanted cells.

Synthesis and functional characterization of a fluorescent peptide probe for non invasive imaging of collagen in live tissues.

Targeted molecular imaging to detect changes in the structural and functional organization of tissues, at the molecular level, is a promising approach for effective and early diagnosis of diseases. Quantitative and qualitative changes in type I collagen, which is a major component in the extra cellular matrix (ECM) of skin and other vital organs like lung, liver, heart and kidneys, are often associated with the pathophysiology of these organs. We have synthesized a fluorescent probe that comprises collagelin, a specific collagen binding peptide, coupled to fluorescent porphyrin that can effectively detect abnormal deposition of collagen in live tissues by emitting fluorescence in the near infra red (NIR) region. In this report we have presented the methodology for coupling of 5-(4-carboxy phenyl)-10, 15, 20-triphenyl porphyrin (C-TPP) to the N-terminal of collagelin or to another mutant peptide (used as a control). We have evaluated the efficacy of these fluorescent peptides to detect collagen deposition in live normal and abnormal tissues. Our results strongly suggest that porphyrin-tagged collagelin can be used as an effective probe for the non invasive in vivo detection of tissue fibrosis, especially in the liver.