Developing a Sustainable Care Delivery Payment Model for Children With Medical Complexity.

Children with medical complexity (CMC) are a small but growing population representing <1% of all children while accounting for >30% of childhood health care expenditure. Complex care is a relatively new discipline that has emerged with goals of improving CMC care, optimizing CMC family function, and reducing health care costs. The provision of care coordination services is a major function of most complex care programs. Unfortunately, most complex care programs struggle to achieve financial sustainability in a predominately fee-for-service environment. The article describes how 2 programs in Wisconsin worked with their state Medicaid payer through a Centers for Medicare and Medicaid Services Health Care Innovation Award to develop a sustainable complex care payment model, and the value the payment model is currently bringing to stakeholders. Key elements of the process included: Developing a relationship between payer and clinicians that allowed for an understanding of each's viewpoint, use of an accepted clinical service model, and an effort to measure cost of care for the service provided supported by time-study methodology.

Single-parentage assignments reveal negative-assortative mating in an endangered salmonid.

Understanding reproductive patterns in endangered species is critical for supporting their recovery efforts. In this study we use a combination of paired-parent and single-parent assignments to examine the reproductive patterns in an endangered population of sockeye salmon (Oncorhynchus nerka) that uses Redfish Lake in central Idaho as a spawning and nursery lake. Recovery efforts include the release of maturing adults into the lake for volitional spawning. The lake is also inhabited by a population of resident O. nerka that is genetically indistinguishable, but phenotypically smaller, to the maturing adults released into the lake. The resident population is difficult to sample and the reproductive patterns between the two groups are unknown. We used results of paired- and single-parentage assignments to specifically examine the reproductive patterns of male fish released into the lake under an equal sex ratio and a male-biased sex ratio. Assignment results of offspring leaving the lake indicated a reproductive shift by males under the two scenarios. Males displayed an assortative mating pattern under an equal sex ratio and spawned almost exclusively with the released females. Under a male-biased sex ratio most males shifted to a negative-assortative mating pattern and spawned with smaller females from the resident population. These males were younger and smaller than males that spawned with released females suggesting they were unable to compete with larger males for spawning opportunities with the larger, released females. The results provided insights into the reproductive behavior of this endangered population and has implications for recovery efforts.

Deep divergence and apparent sex-biased dispersal revealed by a Y-linked marker in rainbow trout.

Y-chromosome and mitochondrial DNA markers can reveal phylogenetic patterns by allowing tracking of male and female lineages, respectively. We used sequence data from a recently discovered Y-linked marker and a mitochondrial marker to examine phylogeographic structure in the widespread and economically important rainbow trout (Oncorhynchus mykiss). Two distinct geographic groupings that generally correspond to coastal and inland subspecies were evident within the Y-marker network while the mtDNA haplotype network showed little geographic structure. Our results suggest that male-specific behavior has prevented widespread admixture of Y haplotypes and that gene flow between the coastal and inland subspecies has largely occurred through females. This new Y marker may also aid conservation efforts by genetically identifying inland populations that have not hybridized with widely stocked coastal-derived hatchery fish.

Effective number of breeders from sibship reconstruction: empirical evaluations using hatchery steelhead.

Effective population size (Ne ) is among the most important metrics in evolutionary biology. In natural populations, it is often difficult to collect adequate demographic data to calculate Ne directly. Consequently, genetic methods to estimate Ne have been developed. Two Ne estimators based on sibship reconstruction using multilocus genotype data have been developed in recent years: sibship assignment and parentage analysis without parents. In this study, we evaluated the accuracy of sibship reconstruction using a large empirical dataset from five hatchery steelhead populations with known pedigrees and using 95 single nucleotide polymorphism (SNP) markers. We challenged the software COLONY with 2,599,961 known relationships and demonstrated that reconstruction of full-sib and unrelated pairs was greater than 95% and 99% accurate, respectively. However, reconstruction of half-sib pairs was poor (<5% accurate). Despite poor half-sib reconstruction, both estimators provided accurate estimates of the effective number of breeders (Nb ) when sample sizes were near or greater than the true Nb and when assuming a monogamous mating system. We further demonstrated that both methods provide roughly equivalent estimates of Nb . Our results indicate that sibship reconstruction and current SNP panels provide promise for estimating Nb in steelhead populations in the region.

Universal mtDNA primers for species identification of degraded bony fish samples.

We developed primers for amplifying and sequencing highly degraded mtDNA from diverse fish species. The primers flank a variable 148-bp fragment within the 12S region of mtDNA. We screened and sequenced 82 samples of bony fishes representing 17 families to confirm cross-species amplification and identification. Salmonid species were analysed and demonstrate 13 species-specific SNPs within this region. Based on alignments of additional deposited sequences, these primers are conserved in many other species, making them useful for species identification using degraded DNA samples such as archaeological specimens.

Comparative genome mapping reveals evidence of gene conversion between Sox9 paralogs of rainbow trout (Oncorhynchus mykiss).

Considerable evidence suggests that one genome duplication event preceded the divergence of teleost fishes and a second genome duplication event occurred before the radiation of teleosts of the family Salmonidae. Two Sox9 genes have been isolated from a number of teleosts and are called Sox9a and Sox9b. Two Sox9 gene copies have also been isolated from rainbow trout, a salmonid fish and are called Sox9 and Sox9?2. Previous evaluations of the evolutionary history of rainbow trout Sox9 gene copies using phylogenetic reconstructions of their coding regions indicated that they both belong to the Sox9b clade. In this study, we determine the true evolutionary history of Sox9 gene copies in rainbow trout. We show that the locus referred to as Sox9 in rainbow trout is itself duplicated. Mapping of the duplicated Sox9 gene copies indicates that they are co-orthologs of Sox9b while mapping of Sox9?2 indicates that it is an ortholog of Sox9a. This relationship is supported by phylogenetic reconstruction of Sox9 gene copies in teleosts using their 3? untranslated regions. The conflicting phylogenetic topology of Sox9 genes in rainbow trout indicates the occurrence of gene conversion events between Sox9 and Sox9?2 which is supported by a number of recombination analyses.

Phylogeographic incongruence of codistributed amphibian species based on small differences in geographic distribution.

Codistributed species may display either congruent phylogeographic patterns, indicating similar responses to a series of shared climatic and geologic events, or discordant patterns, indicating independent responses. This study compares the phylogeographic patterns of two similarly distributed salamander species within the Pacific Northwest of the United States: Cope's giant salamander (Dicamptodon copei) and Van Dyke's salamander (Plethodon vandykei). Previous studies of P. vandykei support two reciprocally monophyletic lineages corresponding to coastal populations, located from the Olympic Mountains to the mouth of the Columbia River, and inland populations within the Cascade Mountains. We hypothesized that D. copei would have a congruent phylogeographic pattern to P. vandykei due to similarity in distribution and dependence upon similar stream and stream-side habitats. We test this hypothesis by estimating the phylogeny of D. copei using approximately 1800bp of mitochondrial DNA and comparing it to that of P. vandykei. Sympatric populations of D. copei and of P. vandykei display an identical phylogeographic pattern, suggesting similar responses within their shared distribution. Populations of D. copei occurring outside the range of P. vandykei displayed high levels of genetic divergence from those sympatric to P. vandykei. Overall, phylogeographic patterns between the two species were ultimately incongruent due to the high divergence of these allopatric populations. These results provide an example of codistributed species displaying overall incongruent phylogeographic patterns while simultaneously displaying congruent patterns within portions of their shared geographic distribution. This pattern demonstrates that a simple dichotomy of congruent and incongruent phylogeographic patterns of codistributed species may be too simplistic and that more complex intermediate patterns can result even from minor differences in species' ranges.

Coalescent-based hypothesis testing supports multiple Pleistocene refugia in the Pacific Northwest for the Pacific giant salamander (Dicamptodon tenebrosus).

Phylogeographic patterns of many taxa are explained by Pleistocene glaciation. The temperate rainforests within the Pacific Northwest of North America provide an excellent example of this phenomenon, and competing phylogenetic hypotheses exist regarding the number of Pleistocene refugia influencing genetic variation of endemic organisms. One such endemic is the Pacific giant salamander, Dicamptodon tenebrosus. In this study, we estimate this species' phylogeny and use a coalescent modeling approach to test five hypotheses concerning the number, location and divergence times of purported Pleistocene refugia. Single refugium hypotheses include: a northern refugium in the Columbia River Valley and a southern refugium in the Klamath-Siskiyou Mountains. Dual refugia hypotheses include these same refugia but separated at varying times: last glacial maximum (20,000 years ago), mid-Pleistocene (800,000 years ago) and early Pleistocene (1.7 million years ago). Phylogenetic analyses and inferences from nested clade analysis reveal distinct northern and southern lineages expanding from the Columbia River Valley and the Klamath-Siskiyou Mountains, respectively. Results of coalescent simulations reject both single refugium hypotheses and the hypothesis of dual refugia with a separation date in the late Pleistocene but not hypotheses predicting dual refugia with separation in early or mid-Pleistocene. Estimates of time since divergence between northern and southern lineages also indicate separation since early to mid-Pleistocene. Tests for expanding populations using mismatch distributions and 'g' distributions reveal demographic growth in the northern and southern lineages. The combination of these results provides strong evidence that this species was restricted into, and subsequently expanded from, at least two Pleistocene refugia in the Pacific Northwest.

Testing hypotheses of speciation timing in Dicamptodon copei and Dicamptodon aterrimus (Caudata: Dicamptodontidae).

Giant salamanders of the genus Dicamptodon are members of the mesic forest ecosystem that occurs in the Pacific Northwest of North America. We estimate the phylogeny of the genus to test several hypotheses concerning speciation and the origin of current species distributions. Specifically, we test competing a priori hypotheses of dispersal and vicariance to explain the disjunct inland distribution of the Idaho giant salamander (D. aterrimus) and to test the hypothesis of Pleistocene speciation of Cope's giant salamander (D. copei) using Bayesian hypothesis testing. We determined that available outgroups were too divergent to root the phylogeny effectively, and we calculated Bayesian posterior probabilities for each of the 15 possible root placements for this four-taxon group. This analysis placed the root on the branch leading to D. aterrimus, indicating that current distribution and speciation of D. aterrimus fit the ancient vicariance hypothesis and are attributable to the orogeny of the Cascade Mountains rather than recent inland dispersal. Furthermore, test results indicate that D. copei is distantly related to other coastal lineages and likely originated much earlier than the Pleistocene. These results suggest that speciation within the genus is attributable to ancient geologic events, while more recent Pleistocene glaciation has shaped genetic variation and distributions within the extant species.