Presence Of Cellular Material Research Articles

Detection of cellular material within handprints

A novel technique for the visualisation of cellular material has been published harnessing an external binding nucleic acid fluorescence dye, Diamond™ dye (DD), in combination with a digital fluorescence microscope. This technique can effectively detect cellular material on an object transferred by touch allowing targeted collection of latent DNA. Previous studies on the visualisation of touch DNA have focussed on transfer from fingertips only.Here we report on the visualisation of cellular material transferred via twenty different positions over the entire handprint. Three volunteers (a heavy, an intermediate and a light shedder) were asked to press their hands onto a plastic surface with medium pressure for 15 s at undefined time points post-handwashing, creating a complete handprint. DD was applied to the entire area and the presence of cellular material was recorded based on cells within 5 separate frames at each of the 20 positions. All tests were performed in triplicate such that the final dataset contained 1,800 observed frames.This extensive study allows accurate monitoring of cellular transfer deposited by different parts of the hand. Our study highlights which areas of an individual’s hand shed the greatest, or least, amount of cellular material. This simple process can act as a guide for DNA collection from items held within the entire hand, rather than only touched by the fingertips only, such as weapons, knives and steering wheels.

Creation of an Acellular Vaginal Matrix for Potential Vaginal Augmentation and Cloacal Repair.

Our aim was to use porcine vagina to create a vaginal matrix and test its cellular biocompatibility. Vagina was harvested from pigs and decellularized (DC) using a combination of detergents (Triton X-100 and sodium deoxycholate) and enzymes (DNAse/RNAse). The presence of cellular material, collagen structural integrity, and basement membrane proteins were assessed histologically. To address cytocompatibility, porcine adipose-derived mesenchymal stem cells were harvested from abdominal fat together with vaginal epithelial cells and seeded onto the mucosal aspect of the vaginal scaffold. Both cell populations were seeded individually and assessed histologically at days 3 and10. The combination of enzymes and detergents resulted in a totally acellular matrix with very low DNA amount (control=97.5ng/μL±10.8 vs DC=40.1ng/μL±0.33; P=.02). The extracellular matrix showed retention of collagen fibers and elastin and a 50% retention in glycosaminoglycan content (control=1.18μg/mg±0.28; DC=1.35μg/mg±0.1; P=.03) and an intact basement membrane (positive for laminin and collagen IV). Seeded scaffolds showed cell attachment with adipose-derived mesenchymal stem cells and vaginal epithelial cells at days 3 and10. It is possible to generate an acellular porcine vaginal matrix capable of supporting cells to reconstruct the vagina for future preclinical testing, and holds promise for creating clinically relevant-sized tissue for human application.

Macrophage phenotype and remodeling outcomes in response to biologic scaffolds with and without a cellular component

Recently, macrophages have been characterized as having an M1 or M2 phenotype based on receptor expression, cytokine and effector molecule production, and function. The effects of macrophage phenotype upon tissue remodeling following the implantation of a biomaterial are largely unknown. The objectives of this study were to determine the effects of a cellular component within an implanted extracellular matrix (ECM) scaffold upon macrophage phenotype, and to determine the relationship between macrophage phenotype and tissue remodeling. Partial-thickness defects in the abdominal wall musculature of Sprague–Dawley rats were repaired with autologous body wall tissue, acellular allogeneic rat body wall ECM, xenogeneic pig urinary bladder tissue, or acellular xenogeneic pig urinary bladder ECM. At 3, 7, 14, and 28 days the host tissue response was characterized using histologic, immunohistochemical, and RT-PCR methods. The acellular test articles were shown to elicit a predominantly M2 type response and resulted in constructive remodeling, while those containing a cellular component, even an autologous cellular component, elicited a predominantly M1 type response and resulted in deposition of dense connective tissue and/or scarring. We conclude that the presence of cellular material within an ECM scaffold modulates the phenotype of the macrophages participating in the host response following implantation, and that the phenotype of the macrophages participating in the host response appears to be related to tissue remodeling outcome.

Association of mitochondria DNA with viral DNA in purified preparations of poxviruses

The presence of cellular material in purified preparations of Shope fibroma virus (SFV) and two orthopoxviruses (vaccinia and Indiana), was investigated. Mitochondria were observed in purified preparations of SFV by electron microscopy and mitochondrial (mt) DNA was identified in restricted viral DNA by Southern blot hybridization with cloned mouse mt DNA. Mitochondrial DNA was also detected in vaccinia and SFV DNAs extracted from purified virions treated with DNase I followed by core isolation. The viral and mt DNAs could be separated on the basis of their size by agarose gel electrophoresis, but not by their buoyant density by centrifugation in cesium chloride gradients. These findings led us to re-examine previously reported results showing some homology between SFV, a leporipoxvirus and Indiana, an Orthopoxvirus (Berkowitz and Pogo, Virology 142, 437–440, 1985) using cloned fragments of SFV DNA instead of the entire viral DNA. The results indicated that cross-hybridization between SFV and Indiana DNAs was due in part to mt DNA but they also revealed an unrecognized region of homology between the two poxvirus genera.

Intracellular uncoating of type 5 adenovirus deoxyribonucleic acid.

Highly purified, (32)P-labeled type 5 adenovirus was employed to study "uncoating" of viral deoxyribonucleic acid (DNA)-defined as the development of sensitivity to deoxyribonuclease. Viral infectivity and radioactivity adsorbed to KB cells at the same rate, and significant amounts of (32)P did not elute from cells throughout the eclipse period. Kinetic studies of viral penetration, eclipse of infectivity, and uncoating of viral DNA indicated that the three events were closely related temporally, that the rates of each were similar, and that they were completed within 60 to 90 min after infection. Viral penetration, eclipse, and uncoating proceeded normally under conditions which blocked protein synthesis, but they did not occur at 0 to 4 C. Neither viral DNA nor viral protein was degraded to acid-soluble material during the eclipse period. The nature of adenovirus DNA was studied after it was converted intracellularly from deoxyribonuclease-resistant to deoxyribonuclease-susceptible. Intact virions centrifuged in sucrose gradients had a sedimentation coefficient of approximately 800, and viral DNA sedimented as a particle of about 30S. Infection of KB cells with purified (32)P-labeled virus yielded deoxyribonuclease-susceptible viral nucleic acid which was in particles with sedimentation coefficients of 350 to 450S, i.e., greater than 10 times faster than DNA obtained from purified virions which had been disrupted by exposure to pH 10.5. When the DNA from disrupted virions was mixed with cell lysates, its sedimentation characteristics were essentially unchanged by the presence of cellular material.