Acute regression of a melanocytic neoplasm.

Immune-mediated regression of melanocytic neoplasms is predominantly lymphocytic, driven by CD8+ anti-tumoral T-cells and, rarely, natural killer cells. Histopathologic features of regression include effacement of the epidermis, replacement of tumor cells by a fibrotic stroma, varying degrees of chronic inflammation (usually lymphocytes) and melanophages, as well as vascular ectasia and angioplasia. The understanding of regression and the complex immune response in melanoma has led to the development of targeted immunotherapy in melanoma. Here, we report a case of near-complete regression of a melanocytic neoplasm associated with neutrophilic and eosinophilic inflammation, suggesting a non-traditional pathway of regression that has yet to be explored.

Cardiac defects contribute to the pathology of spinal muscular atrophy models.

Spinal muscular atrophy (SMA) is an autosomal recessive disorder, which is the leading genetic cause of infantile death. SMA is the most common inherited motor neuron disease and occurs in approximately 1:6000 live births. The gene responsible for SMA is called Survival Motor Neuron-1 (SMN1). Interestingly, a human-specific copy gene is present on the same region of chromosome 5q, called SMN2. Motor neurons are the primary tissue affected in SMA. Although it is clear that SMA is a neurodegenerative disease, there are clinical reports that suggest that other tissues contribute to the overall phenotype, especially in the most severe forms of the disease. In severe SMA cases, a growing number of congenital heart defects have been identified upon autopsy. The most common defect is a developmental defect referred to as hypoplastic left heart. The purpose of this report is to determine whether cardiac tissue is altered in SMA models and whether this could contribute to SMA pathogenesis. Here we identified early-stage developmental defects in a severe model of SMA. Additionally, pathological responses including fibrosis and oxidative stress markers were observed shortly after birth in a less severe model of disease. Similarly, functional differences were detected between wild-type and early-stage SMA animals. Collectively, this work demonstrates the importance of cardiac development and function in these severe models of SMA.

Pharmacoeconomic Considerations in Treating Actinic Keratosis: An Update.

Actinic keratosis is one of the most common dermatological diagnoses worldwide, especially among the elderly, fair-skinned, and immunocompromised, and is associated with a risk of transformation to skin cancer. With actinic keratosis and skin cancer prevalence increasing as the aged population expands in the US, optimizing treatment strategies may produce cost savings for the healthcare system. Since the time of our last review in 2008, investigation of the economic considerations in treating actinic keratosis has advanced. To provide an update of treatment cost effectiveness and to review factors relating to the costs of care, we conducted a systematic review of pharmacoeconomic publications since December 2008. We identified 11 pharmacoeconomic studies, with one cost-of-treatment, five cost-effectiveness, and five cost-utility analyses. Photodynamic therapy (PDT) was well tolerated and produced a favorable cosmetic outcome in most studies. Ingenol mebutate, the newest but most expensive topical field therapy, 5-fluorouracil, and PDT were the most cost-effective treatments in our review. Patient adherence to therapy and the management of adverse effects were significant contributors to treatment costs. In the US, treatment guidelines and formalized cost-effectiveness analyses for actinic keratosis are absent from the recent literature. Future pharmacoeconomic investigation will depend on up-to-date comparative efficacy data, as well as clarification of rates of, and management strategies for, adverse effects, therapeutic non-adherence, and lesion recurrence.

Transgenic inactivation of murine myostatin does not decrease the severity of disease in a model of Spinal Muscular Atrophy.

Spinal Muscular Atrophy (SMA) is a devastating neurodegenerative disease and is a leading genetic cause of infantile death. SMA is caused by the homozygous loss of Survival Motor Neuron-1 (SMN1). The presence of a nearly identical copy gene called SMN2 has led to the development of several strategies that are designed to elevate SMN levels, and it is clear that SMN2 is an important modifier gene. However, the possibility exists that SMN-independent strategies to lessen the severity of the SMA phenotype could provide insight into disease development as well as aid in the identification of potential therapeutic targets. Muscle enhancement has been considered an interesting target for a variety of neurodegenerative diseases, including SMA. Previously we have shown in SMA mice that delivery of recombinant follistatin resulted in an extension in survival and a general lessening of disease severity. Follistatin is known to functionally block myostatin (MSTN), a potent inhibitor of muscle development. However, follistatin is a multifaceted protein involved in a variety of cellular pathways. To determine whether MSTN inhibition was the primary pathway associated with the previously reported follistatin results, we generated an animal model of SMA in which Mstn was genetically inactivated. In this report we characterize the novel SMA/Mstn model and demonstrate that Mstn inactivation does not significantly enhance muscle development in neonatal animals, nor does it result in an amelioration of the SMA phenotype.