Internal Medicine Residents' Knowledge and Practice of Pulmonary Tuberculosis Diagnosis.

BACKGROUND: Internal medicine physicians are often the first providers to encounter patients with a new diagnosis of tuberculosis. Given the public health risks of missed tuberculosis cases, assessing internal medicine residents' ability to diagnose tuberculosis is important. METHODS: Internal medicine resident knowledge and practice patterns in pulmonary tuberculosis diagnosis at 7 academic hospitals were assessed utilizing (a) a 10-item validated pulmonary tuberculosis diagnosis assessment tool and (b) a retrospective chart review of 343 patients who underwent a pulmonary tuberculosis evaluation while admitted to a resident-staffed internal medicine or infectious disease service. Our primary outcomes were the mean score and percentage of correct responses per assessment tool question, and the percentage of patients who had Centers for Disease Control and Prevention-recommended tuberculosis diagnostic tests obtained. RESULTS: Of the 886 residents who received the assessment, 541 responded, yielding a response rate of 61%. The mean score on the assessment tool (SD) was 4.4 (1.6), and the correct response rate was 57% (311/541) or less on 9 of 10 questions. On chart review, each recommended test was obtained for ≤43% (148/343) of patients, other than chest x-ray (328/343; 96%). A nucleic acid amplification test was obtained for 18% (62/343) of patients, whereas 24% (83/343) had only 1 respiratory sample obtained. Twenty patients were diagnosed with tuberculosis. CONCLUSIONS: Significant knowledge and practice gaps exist in internal medicine residents' abilities to diagnose tuberculosis. As residents represent the future providers who will be evaluating patients with possible tuberculosis, such deficiencies must be addressed.

Cells from the hematopoietic lineage are only present transiently during healing in a mouse model of non-severe burn injury.

INTRODUCTION: The aim of our study is to identify the contribution of hematopoietic-derived cells to burn-wound healing in a non-severe injury. There are many conflicting reports of the contribution of bone marrow-derived cells to wound healing and whether these are hematopoietic or mesenchymal in origin. The role of hematopoietic lineage cells is investigated in this study in the context of the response to burn injury. METHODS: Transgenic mice expressing the LacZ reporter gene in all cells of the hematopoietic lineage underwent a non-severe full-thickness burn injury (8 % of total body surface area). Wounds were assessed for LacZ-positive cells at days 7, 14, and 28 post-injury by using whole-mount staining. Cells were also cultured from the wounds at each time point and analysed for expression of fibroblast and myofibroblast markers. RESULTS: At day 7, positive cells were identified in the wounds representing the inflammatory response. Some dermal cells were also identified at this early stage. At day 14, positive cells were also identified and were cultured from the wound tissue samples. However, by day 28, no positive cells could be detected or cultured from the healed wound tissue. Isolated LacZ-positive cells did not express collagen 1 or α-smooth muscle actin proteins, indicating that they had not differentiated into dermal fibroblast-type cells. CONCLUSIONS: In this model of burn injury, hematopoietic lineage cells were present in the healing wound only transiently and did not appear to contribute to the long-term scar population. This is in contrast with reports demonstrating that fibrocytes contribute a long-term sustained population in scar tissue. This work demonstrates that in a non-severe burn injury model there is a sustained transient contribution of hematopoietic cells to the healed wound. Further characterisation of the types and extent of wounding required to establish a long-term hematopoietic response will be important in determining future cell-based therapies.

Characterisation of the cell suspension harvested from the dermal epidermal junction using a ReCell® kit.

BACKGROUND: The use of non-cultured autologous cells to promote wound healing and in reconstructive procedures is increasing. One common method for preparing these cells is the use of the ReCell(®) device. However, despite its current clinical use, no characterisation of the cell suspension produced using a ReCell(®) device has been published. OBJECTIVE: To characterise the ReCell suspension that is applied to wounds for cell type, viability, yield, stability and proliferative potential. METHODS: The ReCell(®) device was used to harvest cells from a 2 cm(2) piece of split-thickness skin isolated using a dermatome. The resulting cell suspension was analysed for cell yield, cell type, viability over time, proliferative potential and reproducibility. RESULTS: Average viable cell yield was 1.7×10(6)/cm(2) of tissue, with 75.5% of the total cell isolate viable. Total viable cell number was not significantly reduced after 4 h storage at 22°C or 4°C, and was stable for 24 h at 4°C. Proliferative potential was assessed using a colony forming assay, with 0.3% of viable cells isolated forming keratinocyte colonies. Predominantly the suspension contained keratinocytes (64.3±28.8%) and fibroblasts (30.3±14.0%), with a small population of melanocytes also identified (3.5±0.5%). Finally, the supernatant contained low total protein (0.92 mg/ml) and the supernatant had no significant effects on cell viability or growth when applied ex vivo. CONCLUSIONS: These results suggest the ReCell(®) device provides a method for the preparation of a cell suspension with high viability and proliferative potential, containing viable melanocytes and no apparent toxic cell debris. Further work on the sustained viability of these cells in vivo, and in particular after application to the wound, will be important to better understand the potential of the ReCell(®) device in the clinic.

Changes in cutaneous innervation in patients with chronic pain after burns.

BACKGROUND: Chronic pain is a common occurrence for burn patients and has significant impact on quality of life. However, the etiology is not well understood. Understanding the mechanisms underlying the restoration of sensory function and the development of chronic pain after burn is critical to improving long-term outcomes. OBJECTIVE: To determine whether cutaneous innervation in burn patients with chronic pain is altered when compared to patients without chronic pain. METHODS: Twelve patients with unilateral injury and who reported chronic pain were recruited. Each patient underwent sensory function testing and both scar and matched site uninjured skin biopsy. Biopsies were analyzed for total nerve density and nociceptive C-fiber density using immunohistochemistry. Results were compared to a control group of 33 patients with unilateral injury and no reported long-term pain. RESULTS: Sensory function was significantly diminished in scar compared to uninjured tissue in both study groups, but chronic pain patients did not have significantly diminished function when compared to control. Total nerve density was not significantly different between scar and uninjured sites in either group, or between groups. However, the density of nociceptive nerve fibers was significantly elevated in both uninjured (p=0.0193) and scar sites (p=0.0316) of the patients with chronic pain when compared to the control group. CONCLUSIONS: This data suggests that differences in cutaneous innervation may contribute to chronic pain after burn. There also appears to be a systemic difference in cutaneous innervation extending to distal uninjured sites. Therefore efforts to affect cutaneous reinnervation after burn may lead to less patients experiencing chronic pain.

The potential of nanoporous anodic aluminium oxide membranes to influence skin wound repair.

Cells respond to changes in the environment by altering their phenotype. The ability to influence cell behavior by modifying their environment provides an opportunity for therapeutic application, for example, to promote faster wound healing in response to skin injury. Here, we have modified the preparation of an aluminium oxide template to generate large uniform membranes with differing nano-pore sizes. Epidermal cells (keratinocytes) and dermal cells (fibroblasts) readily adhere to these nanoporous membranes. The pore size appears to influence the rate of cell proliferation and migration, important aspects of cell behavior during wound healing. The suitability of the membrane to act as a dressing after a burn injury was assessed in vivo; application of the membrane demonstrated adherence and conformability to the skin surface of a pig, with no observed degradation or detrimental effect on the repair. Our results suggest that keratinocytes are sensitive to changes in topography at the nanoscale level and that this property may be exploited to improve wound repair after tissue injury.

Bone marrow-derived cells in the healing burn wound--more than just inflammation.

Scarring after severe burn is a result of changes in collagen deposition and fibroblast activity that result in repaired but not regenerated tissue. Re-epithelialisation of wounds and dermal cell repopulation has been thought to be driven by cells in the periphery of the wound. However, recent research demonstrated that cells originating from the bone marrow contribute to healing wounds in other tissues and also after incisional injury. We investigated the contribution of bone marrow-derived cells to long-term cell populations in scar tissue (primarily fibroblasts and keratinocytes) after severe burn. Wild-type mice were lethally irradiated and then the bone marrow reconstituted by injection of chimeric bone marrow cells expressing EGFP marker protein. Mice with chimeric bone marrow were then given a burn, either an 1-cm diameter injury (to mimic minor injury) or 2-cm diameter (to mimic moderate injury). Wounds were analysed at days 1, 3, 7, 14, 21, 28, 56 and 120 using FACS and immunohistochemistry to identify the percentage and cell type within the wound originating from the bone marrow. The inflammatory cell infiltrate at the early time-points was bone marrow in origin. At later time-points, we noted that over half of the fibroblast population was bone marrow-derived; we also observed that a small percentage of keratinocytes appeared to be bone marrow in origin. These findings support the theory that the bone marrow plays an important role in providing cells not only for inflammation but also dermal and epidermal cells during burn wound healing. This increases our understanding of cell origins in the healing wound, and has the potential to impact on clinical practice providing a potential mechanism for intervention away from conventional topical treatments and directed instead to systemic treatments affecting the bone marrow response.

Characterization of trifluralin binding with recombinant tubulin from Trypanosoma brucei.

The binding kinetics of five novel trifluralin analogs with recombinant alpha- and beta-tubulin proteins from Trypanosoma brucei rhodesiense was determined. Native tubulin from rats was used to determine the extent of binding of each analog to mammalian tubulin. The results of this study clearly demonstrate two important characteristics of the binding of these trifluralins to tubulin. Firstly, they have specific affinity for trypanosomal tubulin compared with mammalian tubulin irrespective of the chemical composition of the trifluralin analog tested. Secondly, they have a stronger affinity for trypanosomal alpha-tubulin compared with trypanosomal beta-tubulin. In addition, compounds 1007, 1008, 1016, and 1017 have strong binding affinities for alpha-tubulin, with limited binding affinity for mammalian tubulin, which indicates that these compounds selectively bind to trypanosomal tubulin.

Secreted Frizzled related protein-4 (sFRP4) promotes epidermal differentiation and apoptosis.

The skin provides vital protection from infection and dehydration. Maintenance of the skin is through a constant program of proliferation, differentiation and apoptosis of epidermal cells, whereby proliferating cells in the basal layer differentiating to form the keratinized, anucleated stratum corneum. The WNT signalling pathway is known to be important in the skin. WNT signalling has been shown to be important both in epidermal development and in the maintenance and cycling of hair follicles and epidermal stem cells. However, the precise role for this pathway in epidermal differentiation remains unknown. We investigated the role of the WNT signalling inhibitor sFRP4 in epidermal differentiation. sFRP4 is expressed in both normal skin and keratinocytes in culture. Expression of sFRP4 mRNA and protein increases with keratinocyte differentiation and apoptosis, whilst exposure of keratinocytes to exogenous sFRP4 promotes apoptosis and expression of the terminal differentiation marker Involucrin. These data suggest sFRP4 promotes epidermal differentiation.

A peptide inhibitor of c-Jun promotes wound healing in a mouse full-thickness burn model.

Significant damage to tissue surrounding burn injuries occurs after the removal of the thermal source. This damage is caused by a combination of both necrotic and apoptotic cell death in the zone of stasis. Preserving the zone of stasis can reduce the wound size and thereby improve wound healing. We tested whether a peptide previously identified to inhibit necrotic and apoptotic cell death in neurons through c-Jun inhibition could enhance wound healing. We first tested the effects of this peptide on a keratinocyte and fibroblast cell line in culture. The peptide promoted proliferation of keratinocytes but had no effect on fibroblast proliferation, while the peptide also inhibited ultraviolet-induced apoptosis of keratinocytes. We finally tested the peptide in vivo, using a mouse model of burn injury. Wounds that were treated with the peptide reepithelialized faster than controls, while cell death surrounding the wound site was markedly reduced 24 hours postinjury, suggesting that the prevention of apoptosis as well as the proliferative effects of this peptide contribute to the wound healing process. Our data implicate c-Jun in multiple processes during wound repair and demonstrate that treatment of burn injuries using inhibitors of c-Jun dimerization at the time of injury can promote wound healing.

Exogenous metallothionein-IIA promotes accelerated healing after a burn wound.

Severe injury to the epidermal barrier often results in scarring and life-long functional deficits, the outcome worsening with a number of factors including time taken to heal. We have investigated the potential of exogenous metallothionein IIA (Zn(7)-MT-IIA), a naturally occurring small cysteine-rich protein, to accelerate healing of burn wounds in a mouse model. Endogenous MT-I/II expression increased in basal keratinocytes concurrent with reepithelialization after a burn injury, indicating a role for MT-I/II in wound healing. In vitro assays of a human keratinocyte cell line indicated that, compared with saline controls, exogenous Zn(7)-MT-IIA significantly increased cell viability by up to 30% (p<0.05), decreased apoptosis by 13% (p<0.05) and promoted keratinocyte migration by up to 14% (p<0.05), all properties that may be desirable to promote rapid wound repair. Further in vitro assays using immortalized and primary fibroblasts indicated that Zn7-MT-IIA did not affect fibroblast motility or contraction (p>0.05). Topical administration of exogenous Zn(7)-MT-IIA (2 microg/mL) in vivo, immediately postburn accelerated healing, promoted faster reepithelialization (3 days: phosphate-buffered saline (PBS), 8.9+/-0.3 mm diameter vs. MT-I/II, 7.1+/-0.7 mm; 7 days: PBS 5.8+/-0.98 mm vs. MT-I/II, 3.6+/-1.0 mm, p<0.05) and reduced epidermal thickness (MT-I/II: 45+/-4 microm vs. PBS: 101+/-19 microm, p<0.05) compared with controls. Our data suggest that exogenous Zn(7)-MT-IIA may prove a valuable therapeutic for patients with burns and other skin injuries.