The Effect of Social Determinants of Health on Telemedicine Access During the COVID-19 Pandemic.

Social determinants of health contribute to inequalities in access to care and inferior outcomes in pediatric populations. Before the coronavirus disease 2019 (COVID-19) pandemic, telemedicine was shown to be an effective tool to bridge the gap between health care providers and rural or underserved populations. The pandemic has rapidly changed the current landscape of health care. Telemedicine has played a critical role in health care delivery between providers and patients because of the need for social distancing. That being said, it has become apparent that SDOH have affected access to telemedicine for communities that already suffer from inequities in health care access. Solutions directed toward addressing issues such as lack of broadband access, digital literacy and language barriers, and obstacles within the health care system are crucial to ensure telemedicine access is equitable for all patients and does not contribute toward worsening health care disparities. [Pediatr Ann. 2022;51(8):e311-e315.].

Robotic duodeno-duodenostomy creation in a pediatric patient with idiopathic duodenal stricture.

Duodenal stenosis is one of the leading causes of duodenal obstruction in the pediatric population, usually diagnosed in newborns and in Down syndrome patients. It has historically been treated with duodeno-duodenostomy, an operation that is now commonly performed laparoscopically. We present a case of a 10-year-old child with a rare chromosomal abnormality who was diagnosed with a duodenal stricture after presenting with failure to thrive and inability to tolerate tube feeds. Duodeno-duodenostomy was performed using the da Vinci® robot, allowing for improved intra-operative range of motion and control during anastomosis creation, with the same cosmetic benefits of laparoscopic surgery, and subsequent improvement in symptoms postoperatively. This case highlights the utility of robotic surgery in complex operations in the pediatric population.

Elevated TIMP-1 expression is associated with a prometastatic phenotype, disease relapse, and poor survival in neuroblastoma.

Approximately two-thirds of patients with neuroblastoma are found to have metastatic disease at time of diagnosis with frequent skeletal, lymph node, central nervous system, and liver involvement. Using a serial in vivo splenic injection model, we have isolated an aggressive subclone (BE(2)-C/LM2) from MYCN-amplified neuroblastomas that demonstrate an enhanced propensity to develop metastatic liver lesions. BE(2)-C/LM2 subclone cells demonstrate increased adherent, soft agar colony and tumorsphere growth in vitro. Components of the tumor microenvironment regulate cancer progression, via networks of cytokines and growth factors. Cytokine array analysis identified increased TIMP-1 in the plasma of mice injected with BE(2)-C/LM2 subclone cells, leading us to hypothesize that TIMP-1 may play a role in our observed prometastatic phenotype. Immunoblotting and ELISA demonstrated enhanced endogenous TIMP-1 expression in our isolated neuroblastoma subclone. Silencing endogenous TIMP-1 successfully blocked in vitro proliferation, soft agar colony formation and tumorsphere formation by BE(2)-C/LM2 cells. Stable RNA interference of endogenous TIMP-1 failed to reverse the prometastatic phenotype of our BE(2)-C/LM2 subclone in our liver metastasis model, suggesting that endogenous TIMP-1 levels may not be an essential component of this in vivo behavior. Notably, tissue microarray analysis and Kaplan-Meier by gene expression demonstrates that elevated TIMP-1 expression is correlated with increased disease relapse and mortality in patients with neuroblastoma. Taken together, our study identifies TIMP-1 as a novel soluble factor that is associated with a prometastatic phenotype in our in vivo model and adverse outcomes in patients with neuroblastoma.

Bromodomain and extraterminal inhibition blocks tumor progression and promotes differentiation in neuroblastoma.

BACKGROUND: MYCN amplification is a key molecular hallmark of high-risk neuroblastoma. Previously considered an "undruggable" target, MYCN transcription can be disrupted by inhibiting the bromodomain and the extraterminal (BET) domain family of proteins that regulates MYCN transcription epigenetically. JQ1 is a potent, small-molecule BET inhibitor that induces cell-cycle arrest and initiates apoptosis in neuroblastoma. Here, we sought to validate the antitumorigenic effects of JQ1 in neuroblastoma and to evaluate whether blocking N-myc expression with JQ1 promotes neural differentiation. METHODS: We determined the effects in vitro of JQ1 treatment on human neuroblastoma cell growth in both monolayer and sphere-forming conditions. Subcutaneous neuroblastoma xenografts were used for an in vivo study. Western blotting and immunohistochemistry were performed to evaluate the effects on neural differentiation and stem cell markers. RESULTS: JQ1 treatment blocked neuroblastoma cell growth in both monolayer and sphere-forming conditions; JQ1 also attenuated the growth of neuroblastoma xenograft in athymic nude mice. Neurofilament expression was enhanced with JQ1 treatment, indicating that JQ1 induces neuronal differentiation. Sphere forming conditions resulted in increased expression of multiple stem cell markers; these effects were reversed with JQ1 treatment. CONCLUSION: BET inhibition attenuates progression and promotes neural differentiation of neuroblastoma in vitro and in vivo in mice, providing insight into potential clinical applications of BET inhibitors in the treatment of patients with neuroblastoma.

Silencing of CDC42 inhibits neuroblastoma cell proliferation and transformation.

Cell division cycle 42 (CDC42), a small GTPase of the Rho-subfamily, regulates diverse cellular functions including proliferation, cytoskeletal rearrangement and even promotes malignant transformation. Here, we found that increased expression of CDC42 correlated with undifferentiated neuroblastoma as compared to a more benign phenotype. CDC42 inhibition decreased cell growth and soft agar colony formation, and increased cell death in BE(2)-C and BE(2)-M17 cell lines, but not in SK-N-AS. In addition, silencing of CDC42 decreased expression of N-myc in BE(2)-C and BE(2)-M17 cells. Our findings suggest that CDC42 may play a role in the regulation of aggressive neuroblastoma behavior.

Targeting aurora kinase A inhibits hypoxia-mediated neuroblastoma cell tumorigenesis.

BACKGROUND/AIM: It is unknown whether hypoxia regulates aurora kinase A (AURKA), a serine/threonine kinase, in neuroblastoma to stimulate cell growth or migration. We sought to determine whether AURKA mediates hypoxia-induced regulation of neuroblastoma tumorigenicity. MATERIALS AND METHODS: Human neuroblastoma BE(2)-C cells were treated with CoCl2, a chemical hypoxia mimetic, and MLN8237, a pharmalogical inhibitor of AURKA, to assess cell viability, colony formation and transwell migration. Focal adhesion kinase (FAK) expression was analyzed after silencing of AURKA under normoxic vs. hypoxic conditions. RESULTS: Hypoxia up-regulated expression of AURKA mRNA and protein. CoCl2 stimulated cell proliferation and migration, while inhibiting colony formation. MLN8237 reduced colony formation and cell migration. Silencing of AURKA reduced expression of FAK and pFAK under normoxia and hypoxia. CONCLUSION: Hypoxia positively regulates AURKA expression. Hypoxia-induced stimulation of colony formation and migration is, in part, mediated by AURKA. These findings establish that AURKA is a critical regulator of hypoxia-mediated tumor progression in neuroblastoma.