How safe is primary knee replacement surgery? Perioperative complication rates in Northern Illinois, 1993–1999

Objective

To describe inpatient complications for primary total knee replacement (TKR) in a period of rapidly growing orthopedic surgery capacity, declining length of stay, and more frequent discharge to rehabilitation facilities.

Methods

Complication incidence according to published coding algorithms was estimated for 35,531 primary TKR admissions of northern Illinois residents to 65 Illinois hospitals. Complication odds were estimated as a function of patients' clinical and sociodemographic status, hospital volume, residency training, TKR length of stay, International Classification of Diseases, Ninth Revision (ICD‐9) coding intensity, and discharges to skilled nursing or rehabilitation facilities.

Results

Primary TKR admissions increased 36% between 1993 and 1999, length of stay declined 43%, average ICD‐9 code use increased 31%, and rehabilitation discharges increased 68%. Major complication rates declined 44% (12.4% to 6.9%; P < 0.0001) over this period, reflecting a 50% reduction in the adjusted odds of complication between 1993 and 1999. There was no association of procedure volume and outcome.

Conclusion

It is likely that the reduction in complications reflects true safety improvements as well as reduced length of stay.

     

CD4+ follicular regulatory T cells optimize the influenza virus–specific B cell response

CD4⁺ follicular regulatory T (Tfr) cells control B cell responses through the modulation of follicular helper T (Tfh) cells and germinal center development while suppressing autoreactivity; however, their role in the regulation of productive germinal center B cell responses and humoral memory is incompletely defined. We show that Tfr cells promote antigen-specific germinal center B cell responses upon influenza virus infection. Following viral challenge, we found that Tfr cells are necessary for robust generation of virus-specific, long-lived plasma cells, antibody production against both hemagglutinin (HA) and neuraminidase (NA), the two major influenza virus glycoproteins, and appropriate regulation of the BCR repertoire. To further investigate the functional relevance of Tfr cells during viral challenge, we used a sequential immunization model with repeated exposure of antigenically partially conserved strains of influenza viruses, revealing that Tfr cells promote recall antibody responses against the conserved HA stalk region. Thus, Tfr cells promote antigen-specific B cell responses and are essential for the development of long-term humoral memory.     

Sparing of the Dystrophin-Deficient Cranial Sartorius Muscle Is Associated with Classical and Novel Hypertrophy Pathways in GRMD Dogs

Both Duchenne and golden retriever muscular dystrophy (GRMD) are caused by dystrophin deficiency. The Duchenne muscular dystrophy sartorius muscle and orthologous GRMD cranial sartorius (CS) are relatively spared/hypertrophied. We completed hierarchical clustering studies to define molecular mechanisms contributing to this differential involvement and their role in the GRMD phenotype. GRMD dogs with larger CS muscles had more severe deficits, suggesting that selective hypertrophy could be detrimental. Serial biopsies from the hypertrophied CS and other atrophied muscles were studied in a subset of these dogs. Myostatin showed an age-dependent decrease and an inverse correlation with the degree of GRMD CS hypertrophy. Regulators of myostatin at the protein (AKT1) and miRNA (miR-539 and miR-208b targeting myostatin mRNA) levels were altered in GRMD CS, consistent with down-regulation of myostatin signaling, CS hypertrophy, and functional rescue of this muscle. mRNA and proteomic profiling was used to identify additional candidate genes associated with CS hypertrophy. The top-ranked network included α-dystroglycan and like-acetylglucosaminyltransferase. Proteomics demonstrated increases in myotrophin and spectrin that could promote hypertrophy and cytoskeletal stability, respectively. Our results suggest that multiple pathways, including decreased myostatin and up-regulated miRNAs, α-dystroglycan/like-acetylglucosaminyltransferase, spectrin, and myotrophin, contribute to hypertrophy and functional sparing of the CS. These data also underscore the muscle-specific responses to dystrophin deficiency and the potential deleterious effects of differential muscle involvement.Duchenne muscular dystrophy (DMD) is an X-linked recessive disorder caused by mutations in the dystrophin gene and occurs in approximately 1 in 3500 live male births.¹ DMD boys show signs of skeletal muscle weakness, evidenced by a delay in walking until approximately 18 months and loss of ambulation by the teenage years. Necrotic muscle ultimately fails to regenerate and is replaced with fibrous connective tissue and fat. Molecular and cellular mechanisms underlying gradual muscle deterioration are poorly understood.Animal models of DMD include the mdx mouse and golden retriever muscular dystrophy (GRMD) dog.^2,3 Despite sharing the same fundamental genetic and biochemical lesions, remarkable phenotypic variation occurs among dystrophin-deficient individuals and muscles. Mdx mice have a relatively mild phenotype,⁴ whereas affected dogs have clinical and pathological features consistent with those of DMD.⁵ Even among DMD patients, who all lack dystrophin except for rare revertant fibers, symptoms can vary markedly.⁶ Dogs with GRMD also demonstrate pronounced phenotypic variation, as some dogs lose the ability to walk within the first 6 months of life, whereas others remain ambulatory to 10 years of age or older.^7–9In GRMD neonatal dogs, flexor muscles such as the sartorius are generally more severely involved than extensors, potentially due to their role in crawling.^10,11 Early dystrophic histopathological changes seen in these diseased muscles include myofiber necrosis evidenced by hyaline fibers, mineralization, edema, and inflammation, with associated regeneration.¹⁰ Presumably, as dogs subsequently begin to walk, weight-bearing extensor muscles such as the vastus lateralis (VL) are more predisposed to injury and display these same acute dystrophic changes. With regard to individual muscle variation in DMD, extensors that undergo eccentric contraction (eg, quadriceps femoris) are particularly vulnerable to early weakness and wasting.¹² On the other hand, the extraocular muscles are largely spared.¹³In DMD patients, most muscles atrophy over time, but some, such as the gastrocnemius, undergo gross enlargement.¹⁴ On the basis of early histological studies of dystrophic muscle biopsies, this calf hypertrophy was initially attributed to deposition of fat and fibrotic tissue and was termed pseudohypertrophy.¹⁵ However, in a series of 350 neuromuscular patients, including 9 with Becker muscular dystrophy, quantitative ultrasound demonstrated that calf hypertrophy was most often due to an actual increase in contractile tissue.¹⁶ Mdx mice¹⁷ and dystrophin-deficient cats¹⁸ also have muscle hypertrophy in the absence of significant fat and connective tissue infiltration. The sartorius muscle is particularly intriguing in both DMD and GRMD. Humans have a single muscle, whereas dogs have cranial and caudal bellies. Serving principally as a hip flexor, the sartorius extends from the pelvis to the proximal tibia in people. Both heads of the canine sartorius also arise from the pelvis, but they insert at different sites (caudal, proximal tibia; cranial, distal femur). The cranial sartorius (CS) muscle of neonatal GRMD dogs sustains extensive necrosis¹⁹ and then regenerates, often undergoing dramatic true hypertrophy.^9,20 In DMD patients, the sartorius muscle is relatively spared and may hypertrophy late in the disease process.^21,22Studies showing variable phenotypes among dystrophin-deficient species, individuals, and muscles suggest that factors other than dystrophin deficiency, so-called secondary effects, are involved in the disease process.²³ Determining the molecular underpinnings of the variable clinical and histopathological response to dystrophin deficiency should provide insight into disease pathogenesis and an opportunity to identify potential targets for therapy. Phenotypic–molecular correlations are inherently limited in DMD patients due to unavoidable restrictions of muscle sampling. Animal studies are potentially more powerful because multiple muscles can be sampled at different ages, thus allowing clearer distinction of factors contributing to disease progression. We chose to use the GRMD model of DMD for this study because of the availability of archived biopsy samples of multiple muscles from affected dogs at two ages and corresponding systematic functional data that could be correlated with mRNA and protein expression findings.Hierarchical clustering of several phenotypic markers, including CS muscle size, tibiotarsal joint angle,⁷ and flexor and extensor torque,⁸ was first performed in a group of GRMD and normal dogs. Consistent with our prior studies,⁹ severely affected dogs tended to have larger CS muscles. To achieve a better understanding of the molecular signals that drive muscle hypertrophy, we extended a prior, largely pathological study of differential muscle involvement in the GRMD model.¹⁹ Proteins that are well known to influence muscle size [myostatin (MSTN)]^24,25 or potentially compensate for dystrophin deficiency [utrophin (UTRN)]²⁶ were assessed in a subset of the dogs evaluated by hierarchical clustering. MSTN showed an age-dependent decrease and an inverse correlation with the degree of CS hypertrophy. Regulators of MSTN at the protein (AKT1) and miRNA (miR-539 and miR-208b targeting myostatin mRNA) level were altered, consistent with down-regulation of MSTN signaling, CS hypertrophy, and functional rescue of this muscle. The growth factor myotrophin (MTPN) was increased in the CS. These studies were augmented by analysis of mRNA, miRNA, and proteomic profiles from several GRMD muscles at two different ages to elucidate additional hypertrophic pathways. Although UTRN was also uniformly increased in GRMD muscles, there was no association with CS size. Other membrane-associated proteins, including α-dystroglycan, like-acetylglucosaminyltransferase (LARGE), and β-spectrin, were increased in the GRMD CS, consistent with a role in membrane stabilization. These results indicate that several muscle proteins may act together to stabilize myofibers and promote muscle growth. Our findings also further substantiate that differential muscle involvement can exaggerate the GRMD phenotype. This suggests that care should be taken with treatments targeting specific pathways, such as MSTN, that could selectively exaggerate muscle hypertrophy.     

Mask-Guided Convolutional Neural Network for Breast Tumor Prognostic Outcome Prediction on 3D DCE-MR Images

Journal of Digital Imaging - In this proof-of-concept work, we have developed a 3D-CNN architecture that is guided by the tumor mask for classifying several patient-outcomes in breast cancer from...     

Use of Cone-beam Computed Tomography as a Critical Component in the Diagnosis of an Infected Nasopalatine Duct Cyst Mimicking Chronic Apical Abscess: A Case Report

Nasopalatine duct cysts (NPDCs) and other nonodontogenic lesions of the oral cavity may mimic odontogenic pathoses. We present a case of a 22-year-old man with a history of dental trauma and a lesion displaying the typical clinical and radiographic signs of a chronic apical abscess— a buccal sinus tract that was traced to a radiolucent area in the periapex of a maxillary central incisor. A comprehensive diagnostic process that included a cone-beam computed tomographic scan and a histopathologic examination of the lesion after complete enucleation led to the final diagnosis of an infected NPDC. The adjacent tooth was vital at the 1-year posttreatment follow-up, and a radiograph demonstrated complete healing of the periradicular structures. This case demonstrates the ability of NPDCs to present clinical and radiographic signs similar to apical inflammatory lesions and the need for a meticulous diagnostic process in order to avoid unnecessary endodontic intervention. The article also discusses the differential diagnoses of nonodontogenic lesions in the premaxillary area.