Infantile hemangioma: timely diagnosis and treatment

A novel therapeutic approach to hemangiomas: Combining photothermal therapy and ferroptosis in a microneedle delivery system

Infantile Hemangioma (IH) is the most common benign vascular tumor occurred in infants and young children. The larger hemangiomas or lesions located in specific areas can cause severe complications, such as disfigurement, obstruction, or ulceration, increasing the risk of functional impairment. Propranolol, serving as the first-line drug for IH treatment, still poses various challenges. Certain patients exhibit low sensitivity to propranolol therapy or face recurrence, which become the leading reason for the failure of IH treatment. Additionally, the requirement for frequent daily medication can also complicate adherence for patients. Hence, developing novel IH therapy methods or drug administration routes is significantly important to enhance therapeutic effect and reduce side effects. Accordingly, in this study, we introduced an innovative photothermal, dissolving microneedles (MNs) patch designed specifically for IH therapy. Firstly, a pH responsive self-assembly nanoplatform with photothermal effect is designed by encapsulating propranolol (PRN) into zeolitic imidazolate framework-8 (ZIF-8) NPs and modifying with TA/Fe nanocomplexes. The fabricated PRN@ZIF-8@TA/Fe (PZ@TA/Fe) NPs exhibited good biocompatibility, pH-responsive degradation, photothermal conversion efficiency inside hemangioma endothelial cells (HemECs). Importantly, TA/Fe surface modification led to intracellular iron overload, which subsequently induced the Fenton reaction and triggered ferroptosis process. The combination of photothermal therapy and ferroptosis therapy exhibited a superior synergistic effect in damaging HemECs and vascular structures. The PZ@TA/Fe NPs loaded in MNs patch further ensured targeted delivery to lesion areas and achieved precise and maximal release of the PZ@TA/Fe NPs, while reducing systemic side effects to normal vasculature or tissue. The PZ@TA/Fe@MNs showed remarkable anti-angiogenic effect against IH in mice model. This study first investigates the potential of ferroptosis therapy in IH treatment, and highlights the substantial therapeutic effect of combining photothermal therapy and ferroptosis effects against IH proliferation. This approach can also become a more effective and safer treatment method for other diseases characterized by abnormal angiogenesis.

The Evaluation, Diagnosis, and Management of Infantile Hemangiomas-A Comprehensive Review

Infantile hemangioma (IH) is the most common pediatric benign vascular tumor. Its pathogenesis is still poorly understood, and it usually appears during the first few weeks of life and follows a characteristic natural course of proliferation and involution. Most IHs are small, benign, resolve spontaneously, and do not require active treatment but only active observation. A minority of IHs are potentially problematic because they can cause life-threatening complications, permanent disfigurement, and functional impairment. Diagnosis is usually clinical, and propranolol is currently the mainstay of treatment. Other therapeutic modalities may be used alone or in combination, depending on the characteristics of the specific IH. New treatment options are being explored every day, and some are showing promising results. It is undeniable that therapeutic modalities for IHs must be selected based on the child's age, the size and location of the lesion, the presence of complications, the implementation conditions, and the possible outcomes of the treatment. The future of IH management will certainly be reflected in improved advanced imaging modalities, research into the genetic and molecular basis, the development of new pharmacological agents or techniques, and the development of standardized protocols, all to optimize outcomes with minimal side effects.

Identification of Diagnostic Markers in Infantile Hemangiomas

Background

Infantile Hemangiomas (IHs) are common benign vascular tumors of infancy that may have serious consequences. The research on diagnostic markers for IHs is scarce.

Methods

The "limma" R package was applied to identify differentially expressed genes (DEGs) in developing IHs. Plugin ClueGO in Cytoscape software performed functional enrichment of DEGs. The Search Tool for Retrieving Interacting Genes (STRING) database was utilized to construct the PPI network. The least absolute shrinkage and selection operator (LASSO) regression model and support vector machine recursive feature elimination (SVM-RFE) analysis were used to identify diagnostic genes for IHs. The receiver operating characteristic (ROC) curve evaluated diagnostic genes' discriminatory ability. Single-gene based on Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) was conducted by Gene Set Enrichment Analysis (GSEA). The chemicals related to the diagnostic genes were excavated by the Comparative Toxicogenomics Database (CTD). Finally, the online website Network Analyst was used to predict the transcription factors targeting the diagnostic genes.

Results

A total of 205 DEGs were singled out from IHs samples of 6-, 12-, and 24-month-old infants. These genes principally participated in vasculogenesis and development-related, endothelial cell-related biological processes. Then we mined 127 interacting proteins and created a network with 127 nodes and 251 edges. Furthermore, LASSO and SVM-RRF algorithms identified five diagnostic genes, namely, TMEM2, GUCY1A2, ISL1, WARS, and STEAP4. ROC curve analysis results indicated that the diagnostic genes had a powerful ability to distinguish IHs samples from normal samples. Next, the results of GSEA for a single gene illustrated that all five diagnostic genes inhibited the "valine, leucine, and isoleucine degradation" pathway in the development of IHs. WARS, TMEM2, and STEAP4 activated the "blood vessel development" and "vasculature development" in IHs. Subsequently, inhibitors targeting TMEM2, GUCY1A2, ISL1, and STEAP4 were mined. Finally, 14 transcription factors regulating GUCY1A2, 14 transcription factors regulating STEAP4, and 26 transcription factors regulating ISL1 were predicted.

Conclusion

This study identified five diagnostic markers for IHs and further explored the mechanisms and targeting drugs, providing a basis for diagnosing and treating IHs.

Clinical practice guidelines on management of infantile hemangioma: a systematic quality appraisal using the AGREE II instrument

Infantile hemangiomas (IH) are the most common benign tumors of childhood. Timely diagnosis and management of higher-risk IH is key in avoiding permanent disfigurement, visual impairment, and life-threatening airway compromise. Here, we identify and critically appraise existing clinical practice guidelines (CPGs) for IH diagnosis and management. A systematic search of MEDLINE, SCOPUS, and EMBASE was conducted until August 2021. Four independent reviewers assessed each CPG utilizing the Appraisal of Guidelines for Research and Evaluation, 2nd edition (AGREE II). An scaled domain score of ≥60% demonstrated adequacy in a given domain. Intraclass correlation coefficients (ICC) assessed agreement and scoring consistency between the reviewers. Eight CPGs were eligible and included for critical appraisal. Only one CPG was classified as 'high quality', with the remaining seven guidelines being 'average' (n = 3) or 'low' (n = 4) quality. Six guidelines (75.0%) were conducted via nonsystematic literature searches. The 'Applicability' (40.4%±14.0) and 'Rigor of development' (46.9%±17.3) domains achieved the lowest scores, while the highest average scores were in 'Scope and purpose' (76.7%±11.3) and 'Editorial independence' (90.8%±13.0). We found high consistency between the four independent reviewers, with 'very good' (n = 5) or 'good' (n = 1) interrater reliability in all six AGREE II domains. Based on the AGREE II instrument, there is only one available high-quality consensus statement on the diagnosis and management of IH. Low scores in 'Rigor of development' and 'Applicability' suggest notable weaknesses in the development process and reporting quality of existing IH CPGs. Future guidelines should be backed by systematic literature searches and focus on guideline clinical translation.