Your search keyword '"J. Fiocchi"' showing total 21 results

1. Additive manufacturing of NiTi architected metamaterials

Author

C.A. Biffi, C. Soyarslan, J. Fiocchi, C. Bregoli, A. du Plessis, A. Tuissi, and M. Mehrpouya

Subjects

Shape memory alloys, Functional performance, Architected metamaterials, Additive manufacturing, Laser Powder Bed Fusion, Industrial engineering. Management engineering, T55.4-60.8

Abstract

Additive manufacturing has revolutionized the creation of complex and intrinsic structures, offering tailored designs for enhanced product performance across various applications. Architected cellular or lattice structures exemplify this innovation, customizable for specific mechanical or functional requirements, boasting advantages such as reduced mass, heightened load-bearing capabilities, and superior energy absorption. Nonetheless, their single-use limitation arises from plastic deformation resulting from localized yield damage or plastic buckling. Incorporating NiTi shape memory alloys (SMAs) presents a solution, enabling structures to recover their original shape post-unloading. In this study, an NiTi architected metastructure, featuring auxetic behavior and a negative Poisson's ratio, was designed and fabricated via laser powder bed fusion (LPBF). The samples exhibit promising superelastic performance with recoverable deformation strains at room temperature. Comprehensive characterization processes evaluated the functional performance of the fabricated metastructures. The metastructure geometry promoted microstructure formation primarily along the wall thickness. Cycling compression tests, conducted at three applied force levels, demonstrated stable cyclic behavior with up to 3.8 % reversible deformation strain, devoid of plastic buckling or yielding damage. Furthermore, the NiTi metastructures displayed robust energy absorption capacity and damping behavior, underscoring their potential for reusable energy dissipators in various industries including aerospace, automotive, construction, and etc.

Published

2024

2. Hot isostatic pressing and heat treatments of LPBFed CoCuFeMnNiTi0.13 high-entropy alloy: microstructure and mechanical properties

Author

J. Fiocchi, C.A. Biffi, M. Elnemr, J. Shipley, A. Tuissi, and R. Casati

Subjects

High-entropy alloys, Laser powder bed fusion, Thermal treatment, Hot isostatic pressing, Microstructure, Mechanical behaviour, Mining engineering. Metallurgy, TN1-997

Abstract

The present work explores the possibility of processing a CoCuFeMnNiTi0.13 high-entropy alloy by laser powder bed fusion (LPBF). The alloy, produced under optimised processing conditions, presents good densification but also hot cracks, caused by the liquation of an inter-dendritic Cu-rich phase. Microstructure of the as-built alloy is characterised by face centred cubic (FCC) columnar grains, containing Cu-poor dendrites and Cu-rich inter-dendritic areas. The alloy, which was designed to be strengthened by spinodal decomposition and precipitation, was subjected to different thermo-mechanical treatments to try and improve its properties. Direct ageing and solution treatment and ageing produced a strong but brittle material (tensile strength of 683 MPa and elongation to failure of 1.3%), whereas hot isostatic pressing followed by controlled cooling was able to heal pores and cracks while triggering the desired microstructural transformations (spinodal decomposition and precipitation). This resulted into a balanced set of mechanical properties (tensile strength of 473 MPa and elongation to failure of 7.6%). This work shows that proper post-processing can mitigate the issues typically affecting LPBF fabricated HEAs, producing tailored microstructures with satisfactory mechanical performances.

Published

2023

3. Relevant aspects of laser cutting of NiTi shape memory alloys

Author

C.A. Biffi, J. Fiocchi, and A. Tuissi

Subjects

Laser material processing, Laser cutting, Shape memory alloy, NiTi, Microstructure, Functional properties, Mining engineering. Metallurgy, TN1-997

Abstract

Since several years the need for realizing small and smart devices composed of functional materials is constantly increasing. Among this advanced materials, shape memory alloys (SMAs) are some of the most important functional materials in several applications, including in the biomedical and aerospace fields. Nowadays, laser cutting is probably the most widespread cutting technology for realising SMA mini- and micro-devices for several applications. The present manuscript reviews the scientific literature on the performance of laser-cut elements, in NiTi SMA, under different points of view. The literature was systematically analysed, according with a technological, metallurgical, functional and device/prototypal approaches. It can be highlighted that a relevant correlation between design, process condition and material performances can promote the realization of advanced smart devices made in NiTi SMA.

Published

2022

4. Effect of laser welding on the mechanical and degradation behaviour of Fe-20Mn-0.6C bioabsorbable alloy

Author

J. Fiocchi, C.A. Biffi, S. Gambaro, C. Paternoster, D. Mantovani, and A. Tuissi

Subjects

Bioabsorbable metallic compounds, Laser welding, Fe-Mn alloys, Microstructure, Mechanical properties, In vitro degradation, Mining engineering. Metallurgy, TN1-997

Abstract

The present work aims at exploring the influence of laser welding on the functional behaviour of a Fe-20Mn-0.6C (wt.%) bioabsorbable alloy. At first, the selection of the most suitable process speed (40 mm/s) was done in order to obtain a full penetration joint with limited taper. Then, microstructural and mechanical analyses of welded sheets confirmed suitable performance of the joint, without porosity, thus preserving chemical composition, mechanical resistance and ductility even after welding. In particular, the base material comprised both γ austenite and ε martensite, while the welded samples showed a further type of martensite, namely α’. Moreover, ultimate tensile strength (1095 MPa and 1104 MPa in base and welded material, respectively) and elongation to failure (61.3% and 60.9%, respectively) were almost not influenced by the welding process. Considering the absorbable nature of these alloys, static immersion degradation tests were carried out, and confirmed that the surface of the welded bead did not exhibit a significant variation of the material degradation rate after 14 days in modified Hanks’ solution. Finally, a significant accumulation of degradation products, mainly (Fe,Mn)CO3, was observed along the joining line.

Published

2020

5. Heat treatment of aluminium alloys produced by laser powder bed fusion: A review

Author

J. Fiocchi, A. Tuissi, and C.A. Biffi

Subjects

Laser powder bed fusion, Selective laser melting, Aluminium alloys, Heat treatment, Microstructure, Mechanical behaviour, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Laser powder bed fusion (LPBF) is the most widely used additive manufacturing technique and has received increasing attention owing to the high design freedom it offers. The production of aluminium alloys by LPBF has attracted considerable interest in several fields due to the low density of the produced alloys. The peculiar solidification conditions experienced by molten metal during the SLM process and its layer-by-layer nature causes a variety of microstructural peculiarities including the formation of metastable phases and supersaturated solid solutions, extreme microstructural refinement, and generation of residual stresses. Therefore, post-build heat treatments, which are commonly applied to conventionally produced aluminium alloys, may need to be modified in order to be adapted to the peculiar metallurgy of aluminium alloys manufactured using LPBF and address the specific issues resulting from the process itself. A number of studies have investigated this topic in recent years, proposing different approaches and dealing with various alloying systems. This paper reviews scientific research results in the field of heat treatment of selective laser melted aluminium alloys; it aims at providing a comprehensive understanding of the relationship between the induced microstructure and the resulting mechanical behaviour, as a function of the various treatment strategies.

Published

2021

6. Selective laser melting of high-strength primary AlSi9Cu3 alloy: Processability, microstructure, and mechanical properties

Author

J. Fiocchi, C.A. Biffi, and A. Tuissi

Subjects

Selective laser melting, Al alloys, AlSi9Cu3, Microstructure, Phase composition, Mechanical properties, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The present work explores the possibility of employing the selective laser melting technique to produce parts in AlSi9Cu3 alloy. This alloy, currently prepared by high-pressure dye casting and intended for automotive application, may benefit from the refined microstructure commonly induced by additive manufacturing techniques. The process parameters were systematically varied to achieve full density, and the resulting defects were studied. Thereafter, microstructural features were analyzed, revealing that the high cooling rate, induced by the process, caused a large supersaturation of the aluminum matrix and the refinement of the eutectic structure. Again, the precipitation of the reinforcing θ phase provided numerous nucleation sites. These features were found to be related to the mechanical behavior of the SLMed AlSi9Cu3 alloy, which outperformed the conventional casted alloy in terms of elongation to failure and strain hardening rate both in the as-built and heat treated conditions.

Published

2020

7. Development and characterization of a novel high entropy alloy strengthened through concurrent spinodal decomposition and precipitation

Author

J. Fiocchi, A. Mostaed, M. Coduri, A. Tuissi, and R. Casati

Subjects

Mechanics of Materials, Mechanical Engineering, Materials Chemistry, Metals and Alloys

Abstract

Strengthening mechanisms, which are commonly exploited by conventional alloys, can be effectively incorporated in high entropy alloys (HEAs) to improve their mechanical behaviour. In this light, compositional modification of equiatomic HEAs can be pursued in order to obtain specific microstructural features. Herein, a face centred cubic CoCuFeMnNi alloy was modified by the addition of a proper amount of Ti; a dedicated thermal treatment allowed to concurrently activate two different phase formation mechanisms, i.e. precipitation and spinodal decomposition. This resulted in a nanostructured microstructure, characterized by the presence of periodic modulations of Cu content and by nanosized coherent L12 Ni3Ti precipitates. Such microstructure resulted in a more than 100 % increase of yield strength after ageing treatment and allowed to retain a satisfactory ductility. Advanced microstructural characterization, coupled with the application of semi-empirical models allowed to understand the role of each microstructural feature in determining the alloy’s mechanical strength.

Published

2023

8. Size-effects affecting the fatigue response up to 109 cycles (VHCF) of SLM AlSi10Mg specimens produced in horizontal and vertical directions

Author

A. Tridello, J. Fiocchi, C.A. Biffi, M. Rossetto, A. Tuissi, and D.S. Paolino

Subjects

Mechanics of Materials, VHCF, Aluminium alloy, Mechanical Engineering, Modeling and Simulation, Additive Manufacturing (AM), Selective Laser Melting (SLM), Size-effect, General Materials Science, Industrial and Manufacturing Engineering

Published

2022

9. Biological Characterization of Ti6Al4V Additively Manufactured Surfaces: Comparison Between Ultrashort Laser Texturing and Conventional Post-Processing.

Author

Sartori M, Bregoli C, Carniato M, Cavazza L, Maglio M, Giavaresi G, Biffi CA, Fiocchi J, Gruppioni E, Tuissi A, and Fini M

Abstract

Among Additive Manufacturing (AM) technologies, Laser Powder Bed Fusion (LPBF) has made a great contribution to optimizing the production of customized implant materials. However, the design of the ideal surface topography, capable of exerting the best biological effect without drawbacks, is still a subject of study. The aim of the present study is to topographically and biologically characterize AM-produced Ti6Al4V ELI (Extra Low Interstitial) samples by comparing different surface finishing. Vertically and horizontally samples are realized by LPBF with four surface finishing conditions (as-built, corundum-sandblasted, zirconia-sandblasted, femtosecond laser textured). Bioactivity in vitro tests are performed with human osteoblasts evaluating morphology, metabolic activity, and differentiation capabilities in direct contact with surfaces. Scanning electron microscope and profilometry analysis are used to evaluate surface morphology and samples' roughness with and without cells. All tested surfaces show good biocompatibility. The influence of material surface features is evident in the early evaluation, with the most promising results of morphological study for laser texturing. Deposition orientations seem to influence metabolic activities, with XZ orientation more effective than XY. Current data provide the first positive feedback on the biocompatibility of laser texturing finishing, still poorly described in the literature, and support the future clinical development of devices produced with a combination of LPBF and different finishing treatments., (© 2024 The Author(s). Advanced Healthcare Materials published by Wiley‐VCH GmbH.)

Published

2024

10. Impact of Surface Finishing on Ti6Al4V Voronoi Additively Manufactured Structures: Morphology, Dimensional Deviation, and Mechanical Behavior.

Author

Bregoli C, Mohajerani S, Fiocchi J, Mehrpouya M, Elahinia M, Tuissi A, Vergani LM, and Biffi CA

Abstract

Additively manufactured medical devices require proper surface finishing before their use to remove partially adhered particles and provide adequate surface roughness. The literature widely investigates regular lattice structures-mainly scaffolds with small pores to enhance osseointegration; however, only a few studies have addressed the impact of surface finishing on the dimensional deviation and the global and local mechanical responses of lattice samples. Therefore, the current research investigates the impact of biomedical surface finishing (i.e., corundum sandblasting and zirconia sandblasting) on Voronoi lattice structures produced by laser powder bed fusion (LPBF) with large pores and different thicknesses on the surface morphology and global and local mechanical behaviors. MicroCT and SEM are performed for the assessment of dimensional mismatch and surface evaluation. The mechanical properties are investigated with 2D digital image correlation (DIC) in quasi-static compression tests to estimate the impact of surface finishes on local maps of strain. In the quasi-static tests, both the global mechanical performances, as expected, and local 2D DIC strain maps were mainly affected by the strut thickness, and the impact of different surface finishings was irrelevant; on the contrary, different surface finishing processes led to differences in the dimensional deviation depending on the strut thickness. These results are relevant for designing lattice structures with thin struts that are integrated into medical prostheses that undergo AM.

Published

2024

11. In Vitro Assessment of the Neuro-Compatibility of Fe-20Mn as a Potential Bioresorbable Material for Craniofacial Surgery.

Author

Ajami S, Kraaneveld C, Koudstaal M, Dunaway D, Jeelani NUO, Schievano S, Bregoli C, Fiocchi J, Biffi CA, Tuissi A, and Borghi A

Subjects

Humans, Materials Testing, Alloys, Stainless Steel, Absorbable Implants

Abstract

Background and Objectives: Spring-assisted surgery is a popular option for the treatment of non-syndromic craniosynostosis. The main drawback of this procedure is the need for a second surgery for spring removal, which could be avoided if a distractor material could be metabolised over time. Iron-Manganese alloys (FeMn) have a good trade-off between degradation rate and strength; however, their biocompatibility is still debated. Materials and Methods: In this study, the neuro-compatibility of Fe-20Mn (wt.%) was assessed using standard assays. PC-12 cells were exposed to Fe-20Mn (wt.%) and stainless steel via indirect contact. To examine the cytotoxicity, a Cell Tox Green assay was carried out after 1, 2, and 3 days of incubation. Following differentiation, a neurite morphological examination after 1 and 7 days of incubation time was carried out. The degradation response in modified Hank's solution at 1, 3, and 7 days was investigated, too. Results: The cytotoxicity assay showed a higher toxicity of Fe-20Mn than stainless steel at earlier time points; however, at the latest time point, no differences were found. Neurite morphology was similar for cells exposed to Fe-20Mn and stainless steel. Conclusions: In conclusion, the Fe-20Mn alloy shows promising neuro-compatibility. Future studies will focus on in vivo studies to confirm the cellular response to Fe-20Mn.

Published

2024

12. High PEEP extubation as guided by esophageal manometry.

Author

Pendleton KM, Fiocchi J, Meyer J, Fuher A, Green S, LeTourneau WM, and Reilkoff RA

Abstract

The ventilatory management of morbidly obese patients presents an ongoing challenge in the Intensive Care Unit (ICU) as multiple physiologic changes in the respiratory system complicate weaning efforts and make extubation more difficult, often leading to increased time on the ventilator. We report the case of a young adult male who presented to our ICU on two separate occasions with hypoxemic respiratory failure requiring intubation. Esophageal manometry (EM) guided positive end expiratory pressure (PEEP) titration was utilized during both ICU admissions to improve oxygenation and aid in extubation with spontaneous breathing trials performed on higher-than-normal PEEP settings and successful liberation on both occasions., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 The Authors.)

Published

2024

13. Bactericidal Activity of Silver-Doped Chitosan Coatings via Electrophoretic Deposition on Ti 6 Al 4 V Additively Manufactured Substrates.

Author

Ghalayani Esfahani A, Sartori M, Bregoli C, Fiocchi J, Biffi CA, Tuissi A, Giavaresi G, Presentato A, Alduina R, De Luca A, Cabrini A, De Capitani C, Fini M, Gruppioni E, Lavorgna M, and Ronca A

Abstract

Prosthetic reconstruction can serve as a feasible alternative, delivering both functional and aesthetic benefits to individuals with hand and finger injuries, frequent causes of emergency room visits. Implant-related infections pose significant challenges in arthroplasty and osteosynthesis procedures, contributing to surgical failures. As a potential solution to this challenge, this study developed a new class of silver (Ag)-doped chitosan (CS) coatings via electrophoretic deposition (EPD) on osseointegrated prostheses for infection therapy. These coatings were successfully applied to additively manufactured Ti 6 Al 4 V ELI samples. In the initial phase, the feasibility of the composite coating was assessed using the Thermogravimetric Analysis (TGA) and Attenuated Total Reflection (ATR) techniques. The optimized structures exhibited impressive water uptake in the range of 300-360%. Codeposition with an antibacterial agent proved effective, and scanning electron microscopy (SEM) was used to examine the coating morphology. Biologically, CS coatings demonstrated cytocompatibility when in direct contact with a fibroblast cell line (L929) after 72 h. When exposed to the Staphylococcus epidermidis strain (ATCC 12228), these coatings inhibited bacterial growth and biofilm formation within 24 h. These findings underscore the significant potential of this approach for various applications, including endoprostheses like hip implants, internal medical devices, and transcutaneous prostheses such as osseointegrated limb prosthetics for upper and lower extremities.

Published

2023

14. A biomechanical study of osseointegrated patient-matched additively manufactured implant for treatment of thumb amputees.

Author

Bregoli C, Stacchiotti F, Fiocchi J, Ferrari R, Biffi CA, Morellato K, Gruppioni E, and Tuissi A

Subjects

Humans, Prosthesis Design, Thumb surgery, Prosthesis Implantation methods, Osseointegration, Amputees

Abstract

Thumb amputations leads to 50 % loss in hand functionality. To date, silicone vacuum prosthesis and autologous transplantation are the most adopted treatment solutions: nevertheless, vacuum prostheses lack in stability and cause skin issue and surgical treatment is not always accepted by patients. Osseointegrated implants were demonstrated to enhance stability, restore osseoperception and increase the time of prosthesis use. Thumb amputations present varying stump sizes: a standard size implant cannot address specificity of each patient, while a patient matched solution can meet surgeon requirements, by geometrical features of implant. The fixture presented in the current paper is the first additively manufactured patient matched osseointegrated implant for the treatment of thumb amputees. The current work aims to verify and validate a predictive finite element model (FEM) for mechanical strength of the presented fixture. FEM was demonstrated to correctly evaluate the mechanical strength of patient matched device. Minimum strength requirements were calculated in different core diameters: FEM were experimentally validated. Safety factor of 1.5 was guaranteed. Finally, considerations on performance of the prototype were carried out by means of insertion tests in Sawbones and axial pull-out force assessment. Cadaver tests to evaluate the entire procedure and production process are ongoing., Competing Interests: Declaration of competing Interest The authors declare no conflict of interest., (Copyright © 2023 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2023

15. Successful hemostasis in refractory alveolar hemorrhage using low-dose recombinant activated factor VII.

Author

Selickman J, Fiocchi J, Desai H, and Pendleton KM

Abstract

Diffuse alveolar hemorrhage (DAH) is a life-threatening condition requiring prompt recognition. Conventional therapy, even when initiated early, may not have an immediate effect, and in severe cases, bleeding can persist despite treatment. We report the case of a previously healthy 33-year-old male who developed DAH secondary to granulomatosis with polyangiitis, resulting in respiratory failure and the need for mechanical ventilation. High-dose corticosteroids, plasma exchange, and remission induction with cyclophosphamide failed to control bleeding, leading to severely impaired gas exchange. 20 mcg/kg of systemic recombinant activated Factor VII (rFVIIa), a dose lower than previously reported for management of DAH, resulted in hemostasis and improved oxygenation after only three doses. No complications were observed, and our patient was liberated from ventilatory support eight days later. In the setting of DAH with refractory bleeding, hemostasis may be achievable with a lower dose of rFVIIa than commonly used, potentially mitigating the risk of dose-dependent side effects., Competing Interests: No conflicts of interest exist for any authors., (© 2022 The Authors. Published by Elsevier Ltd.)

Published

2022

16. A retrospective study on the trends in surgical aortic valve replacement outcomes in the post-transcatheter aortic valve replacement era.

Author

Chahine J, Jedeon Z, Fiocchi J, Shaffer A, Knoper R, John R, Yannopoulos D, Raveendran G, and Gurevich S

Abstract

Background and Aims: Transcatheter aortic valve replacement (TAVR) is the mainstay of treatment of inoperable and severe high-risk aortic stenosis and is noninferior to surgical aortic valve replacement (SAVR) for low-risk and intermediate-risk patients as well. We aim to compare the valve size, area, and transaortic mean gradients in SAVR patients before and after the implementation of TAVR since being approved by the Food and Drug Administration  in 2011., Methods: Patients who underwent a bioprosthetic SAVR placement were divided into two groups based on the date of procedure: the early pre-TAVR implementation group (years 2011-2012) and the contemporary post-TAVR group (years 2019-2020). The primary endpoint was the mean gradient across the aortic valve within 16 months of surgery. The secondary endpoints included the difference in valve size and various aortic valve echocardiographic variables., Results: One hundred and thirty patients had their valves replaced in the years 2011-2012 and 134 in the years 2019-2020. The early group had a significantly higher mean gradient (median of 13 mmHg [interquartile range, IQR: 9.3-18] vs. 10 mmHg [IQR: 7.5-13.1], p  = 0.001) and a smaller median effective orifice area index (0.8 cm 2 /m 2 [IQR: 0.6-1] vs. 1.1 cm 2 /m 2 [IQR: 0.8-1.3], p  < 0.001). The median valve size was significantly smaller in the early group (median of 21 mm [IQR: 21-23] vs. 23 mm [IQR: 22.5-25], p  < 0.001)., Conclusion: In the contemporary era, surgical patients receive larger valves which translates into lower mean gradients, larger valve area, and lower rates of patient-prosthesis mismatch than in previous years before the routine introduction of TAVR., Competing Interests: The authors declare no conflicts of interest., (© 2022 The Authors. Health Science Reports published by Wiley Periodicals LLC.)

Published

2022

17. Resilience of environmental policy amidst the rise of conservative populism.

Author

Mostafavi N, Fiocchi J, Dellacasa MG, and Hoque S

Abstract

Sustainability has for long been promoted as a medium for social and economic development, one that focuses on constant availability of natural assets and ecological amenities. By questioning the possibility of reaching a balanced and sustainable state of functioning for social-ecological systems, resilience improves the static framework of sustainability by acknowledging non-linear behavior of complex systems, inevitability of change, and consistent presence of uncertainty. At the core of sustainable development, environmental policy is embedded in the socio-spatial structures that constantly re-organize and breed uncertainty, such as political, economic, and climate uncertainty. These uncertainties create episodes of instability that shock the entire system including the structures of environmental protection. In this article, focusing on the aftermath of 2016 US presidential election and 2018 general election in Brazil, both broadly recognized as political shocks, we highlight the vulnerabilities of environmental protection structures to the rise of conservative populist movements. We attribute these vulnerabilities, partially, to the superiority of market-based instruments, as well as apolitical understandings of resilience under neoliberalism that overlook political instabilities and socio-spatial outcomes of neoliberal restructuring projects. In our assessment, political unpreparedness of sustainability against the right-wing onslaught in the US and Brazil further underlines the need for resilience theory to incorporate sources of political instability in order to protect the environment., (© The Author(s) 2021.)

Published

2022

18. Heat Treatments for Stress Relieving AlSi9Cu3 Alloy Produced by Laser Powder Bed Fusion.

Author

Fiocchi J, Colombo C, Vergani LM, Fabrizi A, Timelli G, Tuissi A, and Biffi CA

Abstract

The present work explores the effect of a stress relieving heat treatment on the microstructure, tensile properties and residual stresses of the laser powder bed fused AlSi9Cu3 alloy. In fact, the rapid cooling rates together with subsequent heating/cooling cycles occurred during layer by layer additive manufacturing production make low temperature heat treatments desirable for promoting stress relaxation as well as limited grain growth: this combination can offer the opportunity of obtaining the best compromise between high strength, good elongation to failure and limited residual stresses. The microstructural features were analysed, revealing that the high cooling rate, induced by the process, caused a large supersaturation of the aluminum matrix and the refinement of the eutectic structure. Microhardness versus time curve, performed at 250 °C, allowed to identify a stabilization of the mechanical property at a duration of 25 h. The microstructure and the mechanical properties of the samples heat treated at 25 h and at 64 h, considered as a reference for the conventionally produced alloy, were compared with the ones of the as-built alloy. Finally, it was shown that a 59% reduction of the principal residual stresses could be achieved after the 25 h-long treatment and such evolution was correlated to the mechanical behaviour.

Published

2021

19. A Comprehensive Review of the Treatment and Management of Pain in Sickle Cell Disease.

Author

Fiocchi J, Urits I, Orhurhu V, Orhurhu MS, Giacomazzi S, Hoyt B, Kaye AD, Kaye RJ, and Viswanath O

Subjects

Humans, Anemia, Sickle Cell complications, Anemia, Sickle Cell therapy, Chronic Pain etiology, Chronic Pain therapy, Pain Management methods

Abstract

Purpose of Review: Sickle cell disease (SCD) is a hematological disorder which leads to serious complications in multiple organ systems. While significant research has addressed many of the effects of acute pain episodes and end-organ damage connected to this disease, little has approached the chronic pain state associated with this condition., Recent Findings: Associated chronic pain represents a significant detractor from the quality of life experienced by these patients, affecting over half of those with SCD on more days than not. Current treatment typically is centered upon preventing and responding to acute vasoocclusive crises, presumably because this is the most common reason for hospitalization in these patients. The lack of management of chronic pain symptoms leaves many with SCD in a state of suffering. In this review, the treatment methodologies of SCD patients are examined including alternative treatments, both pharmaceutical and non-pharmaceutical, as well as procedural approaches specifically aimed at reducing chronic pain in these patients.

Published

2020

20. Advances in the Understanding and Management of Chronic Pain in Multiple Sclerosis: a Comprehensive Review.

Author

Urits I, Adamian L, Fiocchi J, Hoyt D, Ernst C, Kaye AD, and Viswanath O

Subjects

Humans, Neuralgia etiology, Neuralgia therapy, Chronic Pain etiology, Chronic Pain therapy, Multiple Sclerosis complications, Multiple Sclerosis physiopathology, Pain Management methods

Abstract

Purpose of Review: Multiple sclerosis (MS) is an autoimmune disorder of the central nervous system that can lead to severe physical, cognitive, and neurological deficits that often manifest in young adults. Central neuropathic pain is a common presenting symptom, often prompting patients to seek treatment with opioids, NSAIDS, antiepileptics, and antidepressants despite minimal effectiveness and alarming side-effect profiles. Additionally, spasticity occurs in more than 80% of MS patients and is an important consideration for further study in treatment., Recent Findings: Related to inconsistencies in pain presentation and clinical reporting, current studies continue to investigate clinical patient presentation to define chronic pain characteristics to optimize treatment plans. Although often neuropathic in origin, the complex nature of such pain necessitates a multimodal approach for adequate treatment. While psychiatric comorbidities typically remain unchanged in their severity over time, physical conditions may lead to worsening chronic pain long-term, often due to decreased quality of life. The prevalence of neuropathic pain is ~ 86% in patients with multiple sclerosis and most commonly presents as extremity pain, trigeminal neuralgia, back pain, or headaches. As MS symptoms are frequently unremitting and poorly responsive to conventional medical management, recent attention has been given to novel interventions for management of pain. Among these, medicinal cannabis therapy, targeted physical therapy, and neuromodulation offer promising results. In this review, we provide a comprehensive update of the current perspective of MS pathophysiology, symptomatology, and treatment.

Published

2019

21. CGRP Antagonists for the Treatment of Chronic Migraines: a Comprehensive Review.

Author

Urits I, Jones MR, Gress K, Charipova K, Fiocchi J, Kaye AD, and Viswanath O

Subjects

Chronic Disease, Humans, Migraine Disorders physiopathology, Receptors, Calcitonin Gene-Related Peptide therapeutic use, Treatment Outcome, Antibodies, Monoclonal, Humanized therapeutic use, Calcitonin Gene-Related Peptide Receptor Antagonists therapeutic use, Migraine Disorders drug therapy

Abstract

Purpose of Review: The purpose of the following review is to summarize the most recent understanding of migraine pathophysiology, as well as of basic and clinical science pharmacologic literature regarding the development of calcitonin gene receptor peptide (CGRP) antagonists as a novel therapeutic modality for the treatment of migraine headaches. A review is provided of erenumab, the first of its class FDA approved CGRP antagonist., Recent Findings: Despite its high prevalence, the occurrence and treatment of migraine headaches is poorly understood. Erenumab and CGRP antagonists as a whole significantly reduce the average number of migraine days experienced in migraine sufferers. CGRP antagonists appear to significantly improve treatment outcomes in patients who suffer from episodic and chronic migraines. Erenumab is the first CGRP antagonist to be FDA approved for public use; however, further development of biologics in this class is underway.

Published

2019