Characterization of the mid-coronal plane method for measurement of radiographic change in knee joint space width across different levels of image parallax.

OBJECTIVE: Radiographic measurement of the change in knee joint space width (ΔJSW) is often affected by image parallax, which causes an apparent exaggeration of JSW due to projectional differences. This issue with parallax (quantified by intermargin distance) can in part be addressed with a novel mid-coronal plane (MCP) measurement method. The objectives of the study were to determine 1) accuracy and 2) reproducibility of the MCP method, and 3) compare the MCP method to that used in the Osteoarthritis Initiative (OAI) for different categories of parallax. METHODS: Posteroanterior radiographs (n = 70) with known JSW were digitally reconstructed from CT images of cadaver knees and used to determine the accuracy of ΔJSW using the MCP method for parallax categories of None, Mild/Moderate, and Severe. Reproducibility was determined from pairs of clinical radiographs selected from the OAI (n = 170). The MCP method was also compared to the OAI methodology. Both reproducibility and agreement were characterized by Bland-Altman analysis and intraclass correlation coefficients (ICC). RESULTS: The MCP method was accurate to 0.11 mm in cases with no parallax, and 0.18 mm across all categories of parallax for medial and lateral compartments. Reproducibility of the MCP method was graded "excellent" (ICC 0.98, 95% CI [0.98, 0.99]). The MCP results agreed very well with the OAI (ICC 0.92, 95% CI [0.89, 0.94]), with mean absolute differences between methods increasing with increasing parallax. CONCLUSION: The MCP method is an accurate, reproducible alternative to the OAI method for multi-center clinical trials where subject and X-ray beam positioning may be variable.

Microstructural remodeling of articular cartilage following defect repair by osteochondral autograft transfer.

OBJECTIVE: To assess collagen network alterations occurring with flow and other abnormalities of articular cartilage at medial femoral condyle (MFC) sites repaired with osteochondral autograft (OATS) after 6 and 12 months, using quantitative polarized light microscopy (qPLM) and other histopathological methods. DESIGN: The collagen network structure of articular cartilage of OATS-repaired defects and non-operated contralateral control sites were compared by qPLM analysis of parallelism index (PI), orientation angle (α) relative to the local tissue axes, and retardance (Γ) as a function of depth. qPLM parameter maps were also compared to ICRS and Modified O'Driscoll grades, and cell and matrix sub-scores, for sections stained with H&E and Safranin-O, and for Collagen-I and II. RESULTS: Relative to non-operated normal cartilage, OATS-repaired regions exhibited structural deterioration, with low PI and more horizontal α, and unique structural alteration in adjacent host cartilage: more aligned superficial zone, and reoriented deep zone lateral to the graft, and matrix disorganization in cartilage overhanging the graft. Shifts in α and PI from normal site-specific values were correlated with histochemical abnormalities and co-localized with changes in cell organization/orientation, cloning, or loss, indicative of cartilage flow, remodeling, and deterioration, respectively. CONCLUSIONS: qPLM reveals a number of unique localized alterations of the collagen network in both adjacent host and implanted cartilage in OATS-repaired defects, associated with abnormal chondrocyte organization. These alterations are consistent with mechanobiological processes and the direction and magnitude of cartilage strain.

Statistical shape modeling of proximal femoral shape deformities in Legg-Calvé-Perthes disease and slipped capital femoral epiphysis.

INTRODUCTION: The current understanding of morphological deformities of the hip such as femoroacetabular impingement (FAI), Legg-Calvé-Perthes disease (LCPD), and slipped capital femoral epiphysis (SCFE) is based on two-dimensional metrics, primarily involving the femoral head, that only partially describe the complex skeletal morphology. OBJECTIVE: This study aimed to improve the three-dimensional (3-D) understanding of shape variations during normal growth, and in LCPD and SCFE, through statistical shape modeling. DESIGN: Thirty-two patients with asymptomatic, LCPD, and SCFE hips, determined from physical and radiographic examinations, were scanned using 3-D computed tomography (CT) at a voxel size of (0.5-0.9 mm)(2) in-plane and 0.63 mm slice thickness. Statistical shape modeling was performed on segmented proximal femoral surfaces to determine modes of variation and shape variables quantifying 3-D shape. In addition, conventional variables were determined for all femora. RESULTS: Proximal femur shape was described by eight modes of variation and corresponding shape variables. Statistical shape variables were distinct with age and revealed coordinated, growth-associated differences in neck length-to-width ratio, femoral head medialization, and trochanter protrusion. After size and age-based shape adjustment, diseased proximal femora were characterized by shape variables distinct from those of asymptomatic hips. The shape variables defined morphology in health and disease, and were correlated with certain conventional variables of shape, including neck-shaft angle, head diameter, and neck diameter. CONCLUSION: 3-D quantitative analyses of proximal femoral bone shape during growth and in disease are useful for furthering the understanding of normal and abnormal shape deviations which affect cartilage biomechanics and risk of developing osteoarthritis.

A common human skin tumour is caused by activating mutations in beta-catenin.

WNT signalling orchestrates a number of developmental programs. In response to this stimulus, cytoplasmic beta-catenin (encoded by CTNNB1) is stabilized, enabling downstream transcriptional activation by members of the LEF/TCF family. One of the target genes for beta-catenin/TCF encodes c-MYC, explaining why constitutive activation of the WNT pathway can lead to cancer, particularly in the colon. Most colon cancers arise from mutations in the gene encoding adenomatous polyposis coli (APC), a protein required for ubiquitin-mediated degradation of beta-catenin, but a small percentage of colon and some other cancers harbour beta-catenin-stabilizing mutations. Recently, we discovered that transgenic mice expressing an activated beta-catenin are predisposed to developing skin tumours resembling pilomatricomas. Given that the skin of these adult mice also exhibits signs of de novo hair-follicle morphogenesis, we wondered whether human pilomatricomas might originate from hair matrix cells and whether they might possess beta-catenin-stabilizing mutations. Here, we explore the cell origin and aetiology of this common human skin tumour. We found nuclear LEF-1 in the dividing tumour cells, providing biochemical evidence that pilomatricomas are derived from hair matrix cells. At least 75% of these tumours possess mutations affecting the amino-terminal segment, normally involved in phosphorylation-dependent, ubiquitin-mediated degradation of the protein. This percentage of CTNNB1 mutations is greater than in all other human tumours examined thus far, and directly implicates beta-catenin/LEF misregulation as the major cause of hair matrix cell tumorigenesis in humans.

Contact dermatitis to foods and spices.

Cutaneous reactions to foods and spices occur in both the workplace and at home in those who grow, handle, prepare, or cook food. As spices are also used in cosmetics and perfumes other exposures are found. Several patterns have been described upon contact with food including irritant contact dermatitis, allergic contact dermatitis, contact urticaria, phototoxic contact dermatitis, and protein contact dermatitis. The purpose of this article is to review the approach to a patient suspected of having a cutaneous reaction to food or spices, as well as discuss these reactions and the allergens that cause them.

The derivation and characterization of pig keratinocyte cell lines that retain the ability to differentiate.

Pig skin may be a very useful model for studying human skin biology, since its morphology closely resembles that of human skin. To manipulate pig keratinocytes in vitro, we have analyzed different culture conditions for optimal pig keratinocyte growth and describe here a simple method for culture and extended passage of primary pig keratinocytes on collagen substrates. The colony-forming efficiency and proliferative capacity of primary pig keratinocytes were readily supported by Type I collagen and a final calcium concentration of 0.075 microM. These culture conditions permitted efficient gene transfer into keratinocytes using various cationic lipids at a 4:1 ratio (lipid: DNA). In addition, immortalized pig keratinocyte cell lines, which maintained a normal phenotype, were derived using these optimized culture conditions. By karyotype analysis, two independently derived cell lines had the same chromosomal abnormalities, suggesting a causal role in their immortalization. The keratinocyte cell lines exhibited a differentiated phenotype in response to elevated calcium concentration and were nontumorigenic in in vivo tumor assays. Immortalized pig keratinocyte cell lines that maintain the ability to differentiation may become a valuable tool in the study of epidermal differentiation both in vitro and in vivo. In addition, methods using keratinocytes to deliver genes to pigs in vivo could also be enhanced with these pig keratinocyte cell lines.

Cytokine gene expression in epidermis with biological effects following injection of naked DNA.

The epidermis is readily accessible for genetic manipulation and is easily monitored. Using pig skin because it is very similar to human skin morphologically, we have developed a method to transiently express biologically active factors in epidermis. Following direct injection of naked plasmid DNA into skin, DNA is taken up and transiently expressed at high levels by epidermal keratinocytes. Injection of interleukin-8 plasmid DNA into skin results in the appropriate biological response of neutrophil recruitment, demonstrating functional utility. In addition to this model's therapeutic uses, the biological effects of structural gene products on the epidermis could also be studied in vivo.