Comparing DNA damage caused by formaldehyde, glutaraldehye [sic], Carnoy's and Methacarn in cancer tissue fixations

Tsai, Chia-Jui.

January 2006

Thesis (M.S.)--Bowling Green State University, 2006. / Document formatted into pages; contains ix, 154 p. : ill. Includes bibliographical references.

DNA damage. Fixation (Histology)

Ultra-rapid microwave-stimulated tissue fixation and processing :

Haffajee, Zenobia Ayesha Mohammed.

January 2005

Thesis (MApSc(BiomedicalScience)--University of South Australia, 2005.

Fixation (Histology)

Histology technique.

Microwaves.

Aerosol delivery of mammalian cells for tissue engineering

Roberts, Andrew T.

January 2003

Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: tissue engineering; trachea; chondrocyte; epithelium; aerosol. Includes bibliographical references (p. 64-65).

Maintenance of ultrastructural integrity during dehydration in a desiccation tolerant angiosperm as revealed by improved preservation techniques

Smith, Michaela Madeleine, 1972-

January 2002

Abstract not available

Ultrastructure (Biology)

Fixation (Histology)

Phase partition

Angiosperms

Leaves -- Microbiology

Aerosol Delivery of Mammalian Cells for Tissue Engineering

Roberts, Andrew T

29 April 2003

Every year over 20,000 [3] people die as a result of being in a fire. Although flames have the biggest visual impact, it is usually the smoke produced by the combustion of natural and synthetic materials that causes more damage and claims more lives. The main constituents of smoke, both the particulate matter as well as the hot and toxic gasses, are devastating to the tracheal and lung tissues. The damage caused to the lung and trachea by inhaling this smoke can increase a fire victim's susceptibility to infectious disease significantly [1]. Between 20% and 50% of people who suffer inhalation injury contract pneumonia due to the weakened status of their body's defenses [2] and between 4,800 and 6,400 [1] people die from either pneumonia or other complications. Despite the importance of the inner-lining of the trachea to a burn victim's health and survival, current treatments consist of keeping the patient in a clean environment, supplying fresh oxygen, keeping the airways open, and letting the patient's body heal itself [1]. This treatment is not so much an active healing mechanism; rather it is a passive means of allowing the body to repair itself. The main goal of this work is to develop a minimally invasive technique that will replace lost cells on the inside surface of the trachea as efficiently as possible, actively healing the patient's injury. Ideally, the patient would receive a single treatment and then make a complete recovery on his or her own. The main challenge lies in delivering an even layer of intact cells to the inner-surface of the trachea in such a manner that they will stay in place and will replace the damaged or missing tissue. The overall approach is to spray a suspension, composed of epithelial cells in an aqueous solution of Pluronic F-127 polymer, onto the trachea using a jet atomizer. Because Pluronic F-127 solutions can be liquids at room temperature but gels at body temperature, the role of the polymer will be to immobilize the cells onto the tracheal surface long enough for them to attach and grow.

tissue engineering

trachea

chondrocyte

epithelium

aerosol

Burns and scalds

Treatment

Fixation (Histology)

Trachea

Epithelial cells

The combined effect of formalin fixation and individual steps in tissue processing on immunorecognition

Otali, Dennis.

January 2007

Thesis (M.S.)--University of Alabama at Birmingham, 2007. / Description based on contents viewed Oct. 3, 2008; title from PDF t.p. Includes bibliographical references (p. 64-67).

Photoactivated Fixation of Cartilage Tissue

Sitterle, Valerie B.

20 October 2004

Cartilage repair and/or replacement is necessary for many orthopaedic conditions including fissures from blunt trauma, autograft or allograft transplantation, and replacement of focal defects with biological or synthetic constructs. In cartilage repair, initial integration between the host tissue and repair site is desirable to allow for nutrient transport, molecular deposition to enhance fixation, and eventual stress transmission across the interface. It has been postulated that effective transport and crosslinking of newly synthesized collagen molecules across a repair site may be vital to the process of integrative repair, and recent experiments have correlated collagen deposition with the strength of such repair. Other investigations have shown that enzymatic degradation of the cartilage surface may enhance integrative repair and can increase bond strength of an adhesive to cartilage. This study explored a novel approach involving photochemical bonding of cartilage tissue samples through collagen crosslinking as a means to achieve rapid and effective initial fixation, with the goal of enhancing biological integration. Photosensitized collagen gels were first analyzed via FTIR to determine the crosslinking effects with respect to collagen type and photochemical mechanism. Using the photogellation FTIR results as a parametric guide, in vitro mechanical testing of photochemically bonded meniscal fibrocartilage and hyaline articular cartilage tissues was performed using a modified single-lap shear test. Finally, the cellular viability and bond stability of a photochemically bonded cartilage interface was evaluated over seven days of in vitro culture, where the bond strength was assessed by pushout of cores from annular defects. Results of this study have demonstrated the potential of combining enzymatic surface modification with photodynamic techniques to directly bond cartilage tissues for initial fixation.

Single-lap shear

Enzymatic degradation

Cartilage repair

Photochemical bonding

Photochemistry

Articular cartilage Regeneration

Fixation (Histology)

Collagen