Search Results (855)

Physalis peruviana exhibits highly variable and poorly reproducible morphogenic responses under in vitro conditions, limiting the development of reliable regeneration systems. This study evaluated how the interaction between thidiazuron (TDZ), naphthaleneacetic acid (NAA), and explant type influences shoot regeneration in the Colombiano ecotype of Physalis peruviana. A factorial design (2 × 3 × 2) revealed that morphogenic responses were primarily driven by interaction effects rather than by individual plant growth regulators. Hypocotyl explants cultured in 4.54 µM TDZ combined with 0.6 µM NAA showed the highest shoot production, shoot formation capacity, and elongation. In contrast, TDZ alone induced limited shoot production, did not support efficient and organized shoot development, and was associated with abnormal morphologies. The response to NAA was non-linear, with intermediate concentrations maximizing shoot regeneration response, indicating that morphogenic competence operates within a narrow hormonal range. Overall, regeneration in the Colombiano ecotype of P. peruviana evaluated here was governed by the interaction between hormonal balance and explant type, identifying favorable conditions for shoot regeneration under the conditions tested. Full article

Jatropha curcas L. is an important biofuel plant, but its narrow cultivation range and low seed yield limit its large-scale commercialization. Both genetic improvement and the large-scale clonal propagation of elite genotypes require an efficient and reliable regeneration system. In this study, a high-frequency adventitious shoot regeneration protocol was developed using leaf explants from one-year-old greenhouse-grown plants derived from seeds. An L₉(3³) orthogonal design was employed to optimize the concentrations of plant growth regulators (PGRs). The optimal combination for adventitious shoot induction was 1.0 mg·L⁻¹ TDZ, 0.5 mg·L⁻¹ IBA, and 1.5 mg·L⁻¹ BA. Furthermore, the effect of sodium nitroprusside (SNP), a nitric oxide donor, was investigated. Supplementation with 2.0 mg·L⁻¹ SNP significantly increased both the regeneration frequency and the shoot number per explant when compared to the control. Leaf maturity also significantly influenced the regeneration capacity, with the fourth expanded leaf at the light-green stage showing the greatest response. Under optimized conditions, including PGRs, SNP, and appropriate explant maturity, adventitious shoots were observed within 4 weeks, with a regeneration frequency of 88.0% and an average of 18.7 shoots per explant. This system provides a practical basis for the propagation and genetic improvement of J. curcas. Full article

Autologous tooth-derived grafts are increasingly being investigated for bone regeneration, as dentin shares with bone a mineral phase and an organic matrix rich in type I collagen and non-collagenous proteins. Deciduous teeth are particularly attractive as biomaterials because they are easily obtained after physiological exfoliation, without additional surgical harvesting or donor-site morbidity and may expose a protein-rich matrix after processing. Whether deciduous teeth retain a biologic advantage after prolonged dry storage remains poorly documented. This proof-of-concept ex vivo and in vitro study compared pooled deciduous teeth from six different donors (exfoliated at least 10 years before the experiment and stored dry at room temperature conditions) with six freshly extracted third molars. The teeth were ground using a dedicated device, and conditioned supernatants were collected at 72 h (T1) and 28 days (T2). Osteocalcin, osteonectin, and BMP-2 were quantified by ELISA, and T1 supernatants were applied to human primary osteoblasts to assess the osteogenic response using qRT-PCR and immunofluorescence. Deciduous teeth-conditioned supernatants showed higher osteocalcin and osteonectin release than permanent teeth at both time points, whereas BMP-2 levels were comparable, though with higher values in deciduous samples. In osteoblasts, deciduous teeth-conditioned supernatants induced enhanced osteogenic responses, including greater activation of Collagen I, Osterix, RUNX-2, Osteocalcin, BMP-2 genes, and higher expression of bone-related proteins. Within the limits of this exploratory study, dry-stored deciduous teeth preserved a biologically active dentin matrix and showed a more favorable osteogenic profile than freshly extracted permanent teeth, supporting further investigation into standardized storage protocols and their potential use in regenerative applications. Full article

(1) Background: The role of baseline humoral immunization in bone regeneration remains unclear. This study assessed the relationship between baseline serological immunization, graft type, photobiomodulation (PBM), and histological outcomes after maxillary sinus floor augmentation. (2) Methods: This exploratory secondary analysis included 20 adults undergoing lateral maxillary sinus lifting. Patients were allocated according to graft type (allogeneic or xenogeneic) and postoperative protocol (with or without adjunctive PBM). Before surgery, serum samples were analyzed for anti-HLA class I, anti-HLA class II, and anti-MICA antibodies. After approximately 6 months, bone core biopsies were collected. Histological evaluation focused on inflammatory cell infiltrates (ICI). (3) Results: Baseline antibody positivity was detected in 35.0% of patients for anti-HLA class I, 55.0% for anti-HLA class II, and 45.0% for anti-MICA. Histological findings were generally favorable. ICI scores were low, with 65.0% of samples scoring 0 and 35.0% scoring 1. A nominal positive correlation was observed between anti-HLA class I NBG ratio and ICI; however, this finding did not remain statistically significant after correction for multiple comparisons. Exploratory PBM subgroup estimates were directionally different but were based on very small subgroups and should not be interpreted as evidence of effect modification. (4) Conclusions: The findings suggest a possible hypothesis-generating link between baseline humoral sensitization and mild local inflammatory infiltrates, which requires validation in larger, prospectively powered studies with predefined histological and immunological endpoints. Full article

Deep neural networks (DNNs) have become important intellectual assets, and ownership verification for misappropriated DNNs is increasingly important in Machine Learning as a Service (MLaaS) settings. Among existing DNN watermarking methods, backdoor watermarking is a typical approach for deployed ownership verification. However, existing methods still face two limitations. When verification relies on a finite trigger set, forged ownership evidence becomes difficult to rule out once the trigger samples are leaked or closely imitated. In addition, when watermark embedding modifies the service backbone, the predictor used for routine service is directly altered rather than kept unchanged. To address these limitations, we propose a backdoor DNN watermarking framework that combines secret-key-driven trigger group construction with a plug-and-play LoRA component. The proposed method regenerates the trigger groups used for verification from benign image pairs under a valid key whenever ownership needs to be checked, so ownership verification no longer depends on a finite stored trigger set. Meanwhile, watermark embedding is carried by an external LoRA component rather than by modifying the service backbone. In addition, we further optimize the LoRA configuration through a genetic search. Experiments on five benchmark datasets show that under the intended deployment protocol, the proposed method keeps the service predictor unchanged, enables effective ownership verification, and makes it difficult for attackers without the valid key to reproduce the verification behavior of the legitimate watermark under a large number of repeated attack trials. Full article

Full-arch implant-supported rehabilitations are widely recognized as an effective treatment option for edentulous patients. Nevertheless, clinical decision-making regarding patient selection, surgical planning, prosthetic material choice, and long-term maintenance protocols remains heterogeneous and requires structured evidence-based guidance. A modified Delphi consensus process was conducted involving 29 experts during the Italian Consensus Conference. A systematic literature review covering the period 2015–2024 was performed, and the certainty of evidence was assessed using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) framework. Consensus was predefined as ≥90% agreement. Seven evidence-based consensus statements were developed addressing: (1) periodontal risk assessment using validated tools; (2) guided bone regeneration outcomes with technique-specific indications; (3) comparative survival of four versus six implants in mandibular full-arch rehabilitations; (4) equivalence of tilted and axial implant configurations; (5) prosthetic material selection, with monolithic zirconia showing high survival; (6) risk-stratified supportive maintenance protocols associated with a reduction in peri-implantitis incidence; and (7) systemic risk stratification, including absolute and relative contraindications, medication-related osteonecrosis of the jaw (MRONJ) risk management, and perioperative antibiotic prophylaxis. Full article

Degenerative disc disease is a leading cause of chronic low back pain and disability worldwide, and current treatments primarily address symptoms rather than the underlying biological degeneration of the intervertebral disc. Mesenchymal stem cells (MSCs) have emerged as a promising regenerative approach due to their capacity for differentiation, immunomodulation, and secretion of bioactive factors that promote tissue repair. This review summarises findings from experimental and clinical studies investigating the therapeutic potential of MSC-based therapies for intervertebral disc regeneration, with particular focus on translational challenges that limit their clinical application. Preclinical studies generally show that MSC implantation can enhance extracellular matrix production, improve disc hydration, and modulate inflammatory processes within degenerated discs. Early clinical trials report improvements in pain and functional outcomes; however, consistent structural regeneration has not been reliably demonstrated. The limited clinical translation of MSC therapy is associated with several key challenges, including poor cell survival in the harsh disc microenvironment, variability in cell sources and manufacturing protocols, inadequate cell retention following intradiscal injection, and a lack of standardised outcome measures. In addition, regulatory and manufacturing barriers further complicate the development of reproducible and scalable MSC-based therapies. Although MSC-based therapies represent a promising strategy for the biological treatment of intervertebral disc degeneration, further research is required to improve cell survival, optimise delivery systems, standardise manufacturing procedures, and conduct large-scale controlled clinical trials to establish long-term safety and efficacy. Addressing these translational barriers will be essential for the successful integration of MSC-based therapies into clinical practice. Full article

This review analyzes the advances over a five-year period in the development of polymeric sorbents for the purification of aqueous media from key classes of pollutants: hydrocarbons (crude oil, diesel fuel), organic dyes, pharmaceuticals (antibiotics), pesticides, herbicides, volatile organic compounds, and polycyclic aromatic hydrocarbons. Attention is paid to the analysis of structure-property-performance relationships, with an emphasis on comparing materials derived from renewable natural feedstocks (such as cellulose, chitosan, terpenes, vegetable oils, and aloe vera) with synthetic polymers. The analysis reveals that biopolymer-based sorbents exhibit comparable or superior sorption capacities combined with environmental safety, biodegradability, and low cost. The key sorption mechanisms include physical adsorption, hydrophobic interactions, and electrostatic interactions. Despite persisting challenges related to scalability, stability in real-world environments, and the need for efficient regeneration protocols, a convergent approach that combines the advantages of modified natural polymers and functional synthetic components appears to be the most promising strategy for developing cost-effective and sustainable technologies for the restoration of water quality. Full article

Waterfront brownfield urban public parks (WBUPPs) are complex regeneration projects that require comprehensive assessment of environmental remediation, climate resilience, urban connectivity, and social well-being. This study proposes a structured GIS-based spatial analysis protocol that operationalizes key attributes of brownfields, waterfronts, public parks, and sustainability, with the aim of examining how digital tools can support WBUPP planning processes. Using free and open source resources and datasets (QGIS and OpenStreetMap), the approach produces eight core thematic maps that spatially organize 39 of 50 criteria identified from the literature and classified under economic, environmental, and social sustainability dimensions. This mapping protocol streamlines navigation for planners through complex datasets and offers researchers a foundation for thematic spatial analyses aligned with these literature-based criteria. The protocol is illustrated with Brooklyn Bridge Park in New York City—an 85-acre waterfront redevelopment that demonstrates heritage conservation, ecological restoration, and financial viability. The results highlight identifiable spatial patterns such as dual zones (urban buffer and recreation), winding pathways, and clustered amenities. At the same time, the analysis underscores the importance of data validation, as inconsistencies in volunteered geographic information require cross-referencing with multiple sources and field verification. The analysis shows that WBUPPs require tailored approaches that integrate land–water mobility, heritage adaptation, nature-based solutions, and equitable service distribution. This criteria-driven protocol offers adaptable guidance for future waterfront brownfield regeneration, while emphasizing that digitalization enhances the process, but it cannot replace hybrid analytical methods that combine quantitative spatial analysis with qualitative evaluations. Full article

This study aimed to develop an anther culture protocol for triticale (×Triticosecale Wittmack) and generate a doubled haploid (DH) population combining awnlessness and stripe rust resistance. A wheat anther culture protocol was evaluated on nine triticale varieties, with and without Trichostatin A (TSA), and tested on parental genotypes—an awned, stripe rust–resistant breeding line (AT-45) and an awnless variety (‘1143’)—as well as on ten F₁ plants derived from crosses between AT-45 and ‘1143’. Plant regeneration varied widely among varieties, ranging from 0.8 to 39.7 green plants per 30 anthers (1.6–80 per spike), with an overall mean of 9.9 (20 per spike). TSA did not significantly improve green plant production in this study, though further optimisation of the application method may be warranted. An average of 17.4 green plants per spike was obtained from the F₁ plants, and 1130 regenerant plants were grown to maturity, with a mean spontaneous chromosome doubling rate of 42.5%. A total of 480 DH lines were harvested, comprising 250 awned, 60 reduced awn, and 170 awnless lines. Awned and reduced awn lines were discarded, and 114 awnless lines were advanced for field evaluation of stripe rust resistance and agronomic traits. These results establish an effective anther culture system for DH production in triticale and demonstrate the potential of DH technology to accelerate the development of resilient, high-performing varieties. Full article

A mesostructured activated carbon (PL–AAC) was engineered from palm leaf biomass via a specific chemical activation protocol and systematically evaluated as a bifunctional adsorbent–catalyst for the advanced oxidative removal of methyl orange (MO) from aqueous media. Physicochemical characterization confirmed the successful transformation of the lignocellulosic precursor into a hierarchically porous carbon framework, exhibiting enhanced surface area (2 → 56 m²/g), increased pore volume (0.0106 → 0.0227 cm³/g), and a dominant mesopore distribution (~3–5 nm). FTIR analysis revealed the presence of oxygen-containing functional groups (hydroxyl, carbonyl, and carboxyl), while SEM images demonstrated the formation of interconnected pore channels. Nitrogen adsorption–desorption isotherms showed Type IV behavior with H4 hysteresis, confirming the presence of narrow slit-shaped mesopores and micropores. This study introduces the novel application of palm leaf-derived activated carbon as a dual-function material that integrates adsorption and catalytic oxidation within a single system. Under acidic conditions (pH 2–3), PL–AAC in the presence of H₂O₂ achieved near-complete MO removal (≈98–100%), driven by the synergistic interaction between adsorption and in situ generation of reactive hydroxyl radicals. Kinetic analysis revealed that the degradation follows a pseudo-second-order model (R² = 0.916), indicating that surface-mediated interactions govern the process. Furthermore, PL–AAC maintained high catalytic efficiency over four regeneration cycles with negligible performance loss, demonstrating excellent stability and reusability. These findings highlight the effective valorization of palm leaf waste into a sustainable, low-cost, and high-performance material for advanced wastewater treatment applications. Full article

Lilium longiflorum is a diploid lily species valued for its tolerance to humid–hot environments and pleasant fragrance. However, its poor cold hardiness and low bulb-forming capacity limit its cultivation. To overcome these deficiencies, autotetraploids were previously generated in our laboratory via somatic doubling. In order to expand the reproductive efficiency of the two, this study optimized in vitro regeneration and bulblet enlargement protocols. We analyzed the effects of various plant growth regulators and sucrose concentrations, alongside the expression of genes related to carbohydrate metabolism and hormone signaling. Results revealed divergent regenerative pathways: diploids favored direct organogenesis (optimal medium: MS + 30 g/L sucrose + 0.5 mg/L 6-BA + 0.2 mg/L NAA + 1.0 mg/L glyphosate), whereas tetraploids thrived via a TDZ-induced callus pathway (1/2 MS + 30 g/L sucrose + 1.0 mg/L NAA + 0.2 mg/L TDZ). During bulblet enlargement, diploids were predominantly regulated by IBA and prone to proliferation (optimal enlargement medium: MS + 60 g/L sucrose + 2.0 mg/L IBA), while tetraploids were sucrose-sensitive and prioritized single-bulb hypertrophy (MS + 60 g/L sucrose + 0.5 mg/L IBA + 0.1 mg/L 6-BA + 0.1 mg/L CPPU). qRT-PCR indicated that LlAGPS1, LlGBSSI, LlSWEET15, LlMYC2, and LlSAUR32 were highly expressed in tetraploids during rapid enlargement (24–36 d), suggesting a role in bulb hypertrophy, whereas upregulated LlSUS4 and LlCWIN3 in diploids correlated with proliferation. The study provides a practical technical reference for the industrialized propagation of high-quality L.longiflorum bulbs and provide a theoretical foundation for understanding ploidy-dependent development in Lilium. Full article

Craniofacial and corneal neuropathic pain are disabling conditions characterized by persistent pain that is frequently refractory to conventional pharmacologic and interventional therapies. These disorders arise from complex interactions between peripheral nerve injury, neuroinflammation, and maladaptive central sensitization within trigeminal pathways, features that span neuropathic and nociplastic pain mechanisms as defined by the International Association for the Study of Pain, thus emphasizing the need for mechanism-based, patient-stratified treatment strategies. Regenerative medicine offers a paradigm shift from symptom suppression toward structural nerve repair and functional restoration. This narrative review examines the pathophysiological mechanisms underlying craniofacial and corneal neuropathic pain and critically evaluates emerging regenerative therapies, including autologous biologics (autologous serum tears and platelet-rich plasma), mesenchymal stem cells and their derivatives, exosomes and extracellular vesicles, and neurotrophic peptides. Particular emphasis is placed on corneal neuropathic pain as a translational model, given the cornea’s dense sensory innervation and the ability to non-invasively quantify nerve regeneration using in vivo confocal microscopy as an objective biomarker of treatment response. Clinical evidence across regenerative modalities varies by indication: cenegermin has demonstrated robust efficacy and regulatory approval for neurotrophic keratitis, while platelet-rich plasma shows growing evidence in temporomandibular disorders, myofascial pain, and occipital neuralgia. Cell-based and cell-free therapies demonstrate strong preclinical promise but remain limited by heterogeneous protocols and a paucity of large-scale randomized trials. Key barriers to translation include regulatory uncertainty, lack of standardized outcome measures, and workforce and implementation challenges. Advancing regenerative therapies for craniofacial and corneal neuropathic pain will require rigorous clinical trials, biomarker-driven patient selection, and multidisciplinary collaboration. Sex as a biological variable remains underexplored across all regenerative modalities and represents a priority for future research. Full article

Premature ovarian insufficiency (POI) is a clinical condition characterized by loss of ovarian function indicated by amenorrhea or irregular menstrual cycles for at least 4 months and elevated gonadotrophins (FSH > 25 IU/L, measured on one occasion) and low estrogen serum levels in women under the age of 40. Premature ovarian insufficiency can be non-iatrogenic or spontaneous (idiopathic or due to genetic, autoimmune, or metabolic reasons, or infections) and iatrogenic (a consequence of oophorectomy, chemotherapy, radiotherapy, or uterine artery embolization). Women with POI are faced not only with estrogen deficiency but also with infertility and psychological implications. Hormonal replacement therapy is effective in treating the symptoms of premature ovarian insufficiency as well as in lowering the health risk of long-term consequences of premature ovarian insufficiency. Currently, oocyte donation is the standard treatment for patients with POI desiring pregnancy. Recently developed methods for the regeneration of ovarian tissue, such as stem cell therapy, platelet-reach plasma therapy and in vitro activation of ovarian tissue, are still under research and further adequate multicentric clinical studies are needed to develop standardized effective and safe protocols for the infertility treatment of patients with premature ovarian insufficiency. Full article

The increase in older adults and active lifestyles has made chondral and osteochondral lesions common in the population, making them one of the central challenges in orthopedics. Although hydrogel-based regenerative medicine offers an encouraging therapeutic option for these lesions, important obstacles still prevent these therapies from reaching the clinic. In view of these factors, we adopted a risk-based approach for this review, in line with the current legislative requirements in clinical translation and clinical trials. We identified the factors that could undermine patient safety or lead to poor outcomes. Then, we outlined solutions to remedy these problems that integrate hydrogel technology, clinical/pharmaceutical/surgical protocols, and post-operative follow-up. Upcoming studies should give priority to the development of hydrogel scaffolds modified to mimic cartilage’s mechanical and physicochemical properties, together with patient-specific features. Other crucial characteristics are host-tissue integration, long-lasting cartilage tissue regeneration, and a positive outcome. In parallel, to scale complex and costly innovations, efforts should focus on a harmonized, simplified legislative landscape, optimized standards, and established follow-up protocols. Getting through this “valley of death” between research and innovation is strategic for reaching the clinics and the largest number of patients. Full article