Parallel Proximity Detection for Computer Simulation

The present invention discloses a system for performing proximity detection in computer simulations on parallel processing architectures utilizing a distribution list which includes movers and sensor coverages which check in and out of grids. Each mover maintains a list of sensors that detect the mover's motion as the mover and sensor coverages check in and out of the grids. Fuzzy grids are includes by fuzzy resolution parameters to allow movers and sensor coverages to check in and out of grids without computing exact grid crossings. The movers check in and out of grids while moving sensors periodically inform the grids of their coverage. In addition, a lookahead function is also included for providing a generalized capability without making any limiting assumptions about the particular application to which it is applied. The lookahead function is initiated so that risk-free synchronization strategies never roll back grid events. The lookahead function adds fixed delays as events are scheduled for objects on other nodes

Induction of Paralysis and Visual System Injury in Mice by T Cells Specific for Neuromyelitis Optica Autoantigen Aquaporin-4.

While it is recognized that aquaporin-4 (AQP4)-specific T cells and antibodies participate in the pathogenesis of neuromyelitis optica (NMO), a human central nervous system (CNS) autoimmune demyelinating disease, creation of an AQP4-targeted model with both clinical and histologic manifestations of CNS autoimmunity has proven challenging. Immunization of wild-type (WT) mice with AQP4 peptides elicited T cell proliferation, although those T cells could not transfer disease to naïve recipient mice. Recently, two novel AQP4 T cell epitopes, peptide (p) 135-153 and p201-220, were identified when studying immune responses to AQP4 in AQP4-deficient (AQP4-/-) mice, suggesting T cell reactivity to these epitopes is normally controlled by thymic negative selection. AQP4-/- Th17 polarized T cells primed to either p135-153 or p201-220 induced paralysis in recipient WT mice, that was associated with predominantly leptomeningeal inflammation of the spinal cord and optic nerves. Inflammation surrounding optic nerves and involvement of the inner retinal layers (IRL) were manifested by changes in serial optical coherence tomography (OCT). Here, we illustrate the approaches used to create this new in vivo model of AQP4-targeted CNS autoimmunity (ATCA), which can now be employed to study mechanisms that permit development of pathogenic AQP4-specific T cells and how they may cooperate with B cells in NMO pathogenesis

Migration and maturation of langerhans cells in skin transplants and explants

The behavior of Langerhans cells (LC) has been examined after skin transplantation and in an organ culture system. Within 24 h (and even within 4 h of culture), LC in epidermal sheets from allografts, isografts, and explants dramatically increased in size and expression of major histocompatibility complex class II molecules, and their numbers were markedly decreased. Using a new procedure, dermal sheets were then examined. By 24 h, cells resembling LC were found close to the epidermal-dermal junction, and by 3 d, they formed cords in dermal lymphatics before leaving the skin. In organ culture, the cells continued to migrate spontaneously into the medium. These observations establish a direct route for migration of LC from the epidermis into the dermis and then out of the skin. These processes are apparently induced by a local inflammatory response, and are independent ofhost-derived mediators. The phenotype ofmigratory cells was then examined by two-color immunocytochemistry and FACS analysis. The majority of migratory leukocytes were Ia+ LC, the remainder comprised Thy-1+, CD3 +, CD4−, CD8− presumptive T cell receptor γ/δ+ dendritic epidermal cells, which clustered with the LC, and a small population of adherent Ia−, FcRII+, CD11a/18+ macrophages. In contrast to the cells remaining within the epidermis of grafted skin at 1 d, the migratory cells were heterogeneous in phenotype, particularly with respect to F4/80, FcRII, and interleukin 2 receptor ot expression, which are useful markers to follow phenotypic maturation of LC. Moreover, cells isolated from the epidermis of grafts at 1 d were more immunostimulatory in the allogeneic mixed leukocyte reaction and oxidative mitogenesis than LC isolated from normal skin, though less potent than spleen cells. The day 1 migratory cells were considerably more immunostimulatory than spleen cells, and day 3-5 migratory cells even more so, suggesting that functional maturation continues in culture. Thus, maturation ofLC commences in the epidermis and continues during migration, but the cells do not need to be fully mature in phenotype or function before they leave the skin. In vivo, the migration of epidermal LC via the dermis into lymphatics and then to the draining nodes, where they have been shown previously to home to T areas, would provide a powerful stimulus for graft rejection

Migration and maturation of Langerhans cells in skin transplants and explants

Larsen, C.P., Steinman, R.M., Witmer-Pack, M.D., Hankins, D.F., Morris, P.J., and Austyn, J.M. Migration and maturation of Langerhans cells in skin transplants and explants. J. Exp. Med. 172: 1483-1493, 1990https://digitalcommons.rockefeller.edu/historical-scientific-reports/1030/thumbnail.jp

Mechanisms of mouse spleen dendritic cell function in the generation of influenza-specific, cytolytic T lymphocytes

We have evaluated the capacity of dendritic ceUs to function as antigen-presenting cells (APCs) for influenza and have examined their mechanism of action. Virus-pulsed dendritic cells were 100 times more efficent than bulk spleen ceUs in stimulating cytotoxic T lymphocyte (CTL) formation. The induction of CTLs required neither exogenous lymphokines nor APCs in the responding T cell population. Infectious virus entered dendritic cells through intraceUular acidic vacuoles and directed the synthesis of several viral proteins. If ultravidet (UV)-inactivated or bromdain-treated viruses were used, viral protein synthesis could not be detected, and there was poor induction of CTLs. This indicated that dendritic cells were not capable of processing noninfectious virus onto major histocompatibility complex (MHC) class I molecules. However, UV-inactivated and bromdain-treated viruses were presented efficently to class II-restricted CD4+ T ceils. The CD4+ T cells crossreacted with different strains of influenza and markedly amplified CTL formation. Cell lines that lacked MHC class II, and consequently the capacity to stimulate CD4+ T cells, failed to induce CTLs unless hdper lymphokines were added. Similarly, dendritic cells pulsed with the MHC class I-restricted nucleoprotdn 147-155 peptide were poor stimulators in the absence of exogenous hdper factors. We condude that the function of dendritic cells as APCs for the generation of virus-spedfic CTLs in vitro depends measurably upon: (a) charging class I molecules with peptides derived from endogenously synthesized viral antigens, and (b) stimulating a strong CD4+ helper T cell response

The simian immunodeficiency virus Δnef vaccine, after application to the tonsils of rhesus macaques, replicates primarily within CD4+ T cells and elicits a local perforin-positive CD8+ T-cell response

Deletion of the nef gene from simian immunodeficiency virus (SIV) strain SIVmac239 yields a virus that undergoes attenuated growth in rhesus macaques and offers substantial protection against a subsequent challenge with some SIV wild-type viruses. We used a recently described model to identify sites in which the SIVΔnef vaccine strain replicates and elicits immunity in vivo. A high dose of SIVΔnef was applied to the palatine and lingual tonsils, where it replicated vigorously in this portal of entry at 7 days. Within 2 weeks, the virus had spread and was replicating actively in axillary lymph nodes, primarily in extrafollicular T-cell-rich regions but also in germinal centers. At this time, large numbers of perforin-positive cells, both CD8+ T cells and CD3-negative presumptive natural killer cells, were found in the tonsil and axillary lymph nodes. The number of infected cells and perforin-positive cells then fell. When autopsy studies were carried out at 26 weeks, only 1 to 3 cells hybridized for viral RNA per section of lymphoid tissue. Nevertheless, infected cells were detected chronically in most lymphoid organs, where the titers of infectious virus could exceed by a log or more the titers in blood. Immunocytochemical labeling at the early active stages of infection showed that cells expressing SIVΔnef RNA were CD4+ T lymphocytes. A majority of infected cells were not in the active cell cycle, since 60 to 70% of the RNA-positive cells in tissue sections lacked the Ki-67 cell cycle antigen, and both Ki-67-positive and -negative cells had similar grain counts for viral RNA. Macrophages and dendritic cells, identified with a panel of monoclonal antibodies to these cells, were rarely infected. We conclude that the attenuated growth and protection observed with the SIVΔnef vaccine strain does not require that the virus shift its characteristic site of replication, the CD4+ T lymphocyte. In fact, this immunodeficiency virus can replicate actively in CD4+ T cells prior to being contained by the host, at least in part by a strong killer cell response that is generated acutely in the infected lymph nodes

Evaluating Needs of Older Adults in Massachusetts Communities

Throughout Massachusetts, the ongoing demographic shift toward an older population has required most cities and towns to reevaluate the adequacy of services and programs for older adults. By 2030, the vast majority of municipalities in Massachusetts will have unprecedented proportions of people age 60 or over