Histopathological correlations of bulk tissue polarimetric images: case study

xloma.fota13 shared this article with you from Inoreader Histopathological correlations of bulk tissue polarimetric images: case study Via Journal of Biophotonics Abstract Polarimetric imaging and image analysis have gained increased interest in soft tissue analysis at the cellular level. However, polarimetric imaging has widely been tested on thin tissue sections to provide reliable information correlated with histopathological findings. Polarimetric bulk tissue analysis always offered an overall assessment of various tissue optical properties for diagnosis. In this study, the histopathological correlation of bulk tissue polarimetry images for soft tissues is discussed. The first‐hand information on the use of bulk tissue Mueller polarimetry and image analysis as an alternative to tissue histopathology is presented for surgically extracted colon and breast tissues. This article is protected by copyright. All rights reserved. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

A case of lymphomatoid papulosis type E in a young adult; an uncommon entity

xloma.fota13 shared this article with you from Inoreader A case of lymphomatoid papulosis type E in a young adult; an uncommon entity Via Journal of Cutaneous Pathology Abstract Lymphomatoid papulosis (LyP) type E is a rare variant of the primary cutaneous CD30+ lymphoproliferative disorders, characterized clinically by large necrotic eschar‐like lesions and histopathologically by angiodestructive and angioinvasive infiltrates of CD30+ lymphocytes. As in other forms of lymphomatoid papulosis, type E lesions may undergo spontaneous regression after weeks, with frequent recurrences. We report a 21‐year old male with an angiodestructive infiltrate of CD30+ lymphocytes manifesting as a papular eruption rather than ulceration, and suggest that this clinical phenotype might be related to the presence of CD4+ lymphocytes in the inflammatory cell infiltrate. This article is protected by copyright. All rights reserved. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Can an in vitro hair drug model be developed using dermal papilla cells alone?

xloma.fota13 shared this article with you from Inoreader Can an in vitro hair drug model be developed using dermal papilla cells alone? Via Experimental Dermatology Abstract The search for hair growth drugs is hindered by the lack of in vitro models which adequately mimic the native hair follicle[1]. The in vitro organotypic model accurately reproduces hair drug responses from the hair shaft elongation of cultured hair follicles; however, these can only be maintained for 2 weeks, posing a challenge to obtain sufficient samples for comprehensive and continuous studies[2]. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Substantial alterations of the intestinal microbiota in psoriasis patients

xloma.fota13 shared this article with you from Inoreader Substantial alterations of the intestinal microbiota in psoriasis patients of China Via Experimental Dermatology Abstract Psoriasis is an immune‐mediated inflammatory skin condition. Accumulating evidence suggest that there is an intimate relationship between intestinal dysbiosis and psoriasis. In order to evaluate the specificity of intestinal microflora in patients with psoriasis and to investigate the link between psoriasis and gut microbiota, this study collected stool samples from 20 patients with moderate to severe chronic plaque psoriasis and 20 healthy controls. Methodological details are provided in the online supplementary material. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

An Immunomodulatory Miniaturized 3D Screening Platform Using Liquefied Capsules

xloma.fota13 shared this article with you from Inoreader An Immunomodulatory Miniaturized 3D Screening Platform Using Liquefied Capsules Via Advanced Healthcare Materials Immunomodulatory miniaturized 3D platform using liquefied capsules for the in vitro high‐content combinatorial screening of different biomaterials, cells, and bioinstructive microplatforms. Simply by changing the biomaterial of the last layer of the liquefied capsules, it is possible to proactively modulate the surrounding macrophages behavior, and at the same time, study independently the paracrine signaling with encapsulated cells. Abstract A critical determinant of successful clinical outcomes is the host's response to the biomaterial. Therefore, the prediction of the immunomodulatory bioperformance of biomedical devices following implantation is of utmost importance. Herein, liquefied capsules are proposed as immunomodulatory miniaturized 3D platforms for the high‐content combinatorial screening of different polymers that could be used generically in scaffolds. Additionally, the confined and liquefied core of capsules affords a cell‐mediated 3D assembly with bioinstructive microplatforms, allowing to study the potential synergistic effect that cells in tissue engineering therapies have on the immunological environment before implantation. As a proof‐of‐concept, three different polyelectrolytes, ranging in charge density and source, are used. Poly(L‐lysine)‐, alginate‐, and chitosan‐ending capsules with or without encapsulated mesenchymal stem/stromal cells (MSCs) are placed on top of a 2D culture of macrophages. Results show that chitosan‐ending capsules, as well as the presence of MSCs, favor the balance of macrophage polarization toward a more regenerative profile, through the up‐regulation of anti‐inflammatory markers, and the release of pro‐regenerative cytokines. Overall, the developed system enables the study of the immunomodulatory bioperformance of several polymers in a cost‐effective and scalable fashion, while the paracrine signaling between encapsulated cells and the immunological environment can be simultaneously evaluated. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Preparation of Stretchable Nanofibrous Sheets with Sacrificial Coaxial Electrospinning for Treatment of Traumatic Muscle Injury

xloma.fota13 shared this article with you from Inoreader Preparation of Stretchable Nanofibrous Sheets with Sacrificial Coaxial Electrospinning for Treatment of Traumatic Muscle Injury Via Advanced Healthcare Materials Myogenesis is evaluated on step‐wise stretched gelatin nanofibers in order to apply skeletal muscle regeneration scaffolds. Abstract Traumatic muscle injury with massive loss of muscle volume requires intramuscular implantation of proper scaffolds for fast and successful recovery. Although many artificial scaffolds effectively accelerate formation and maturation of myotubes, limited studies are showing the therapeutic effect of artificial scaffolds in animal models with massive muscle injury. In this study, improved myotube differentiation is approved on stepwise stretched gelatin nanofibers and applied to damaged muscle recovery in an animal model. The gelatin nanofibers are fabricated by a two‐step process composed of co‐axial electrospinning of poly(ɛ‐caprolactone) and gelatin and subsequent removal of the outer shells. When stepwise stretching is applied to the myoblasts on gelatin nanofibers for five days, enhanced myotube formation and polarized elongation are observed. Animal models with volumetric loss at quadriceps femoris muscles (>50%) are transplanted with the myotubes cultivated on thin a nd flexible gelatin nanofiber. Treated animals more efficiently recover exercising functions of the leg when myotubes and the gelatin nanofiber are co‐implanted at the injury sites. This result suggests that mechanically stimulated myotubes on gelatin nanofiber is therapeutically feasible for the robust recovery of volumetric muscle loss. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Biomimetic Tympanic Membrane Replacement Made by Melt Electrowriting

xloma.fota13 shared this article with you from Inoreader Biomimetic Tympanic Membrane Replacement Made by Melt Electrowriting Via Advanced Healthcare Materials Melt electrowriting (MEW) is utilized for fabrication of biomimetic tympanic membrane (TM) replacements. These novel materials transfer the complete frequency range of the human speech while offering comparable mechanical properties to the human TM. Excellent biocompatibility is demonstrated using human keratinocytes. Coating of the MEW membranes with a sub‐µm collagen layer further improves the acoustic properties and facilitates cell adhesion. Abstract The tympanic membrane (TM) transfers sound waves from the air into mechanical motion for the ossicular chain. This requires a high sensitivity to small dynamic pressure changes and resistance to large quasi‐static pressure differences. The TM achieves this by providing a layered structure of about 100µm in thickness, a low flexural stiffness, and a high tensile strength. Chronically infected middle ears require reconstruction of a large area of the TM. However, current clinical treatment can cause a reduction in hearing. With the novel additive manufacturing technique of melt electrowriting (MEW), it is for the first time possible to fabricate highly organized and biodegradable membranes within the dimensions of the TM. Scaffold designs of various fiber composition are analyzed mechanically and acoustically. It can be demonstrated that by customizing fiber orientation, fiber diameter, and number of layers the desired properties of the TM can be met. An applied thin collagen lay er seals the micropores of the MEW‐printed membrane while keeping the favorable mechanical and acoustical characteristics. The determined properties are beneficial for implantation, closely match those of the human TM, and support the growth of a neo‐epithelial layer. This proves the possibilities to create a biomimimetic TM replacement using MEW. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Rational Design of Nanomaterials for Various Radiation‐Induced Diseases Prevention and Treatment

xloma.fota13 shared this article with you from Inoreader Rational Design of Nanomaterials for Various Radiation‐Induced Diseases Prevention and Treatment Via Advanced Healthcare Materials This review systematically sums up the advances and perspectives in the rational design of nanomaterial for various general radiation‐induced diseases. Meanwhile, the sources, clinical symptoms, and pathogenesis/injury mechanisms of various general radiation‐induced diseases are comprehensively introduced. Abstract Radiation treatments often unfavorably damage neighboring healthy organs and cause a series of radiation sequelae, such as radiation‐induced hematopoietic system diseases, radiation‐induced gastrointestinal diseases, radiation‐induced lung diseases, and radiation‐induced skin diseases. Recently, emerging nanomaterials have exhibited good superiority for these radiation‐induced disease treatments. Given this background, the rational design principle of nanomaterials, which helps to optimize the therapeutic efficiency, has been an increasing need. Consequently, it is of great significance to perform a systematic summarization of the advances in this field, which can trigger the development of new high‐performance nanoradioprotectors with drug efficiency maximization. Herein, this review highlights the advances and perspectives in the rational design of nanomaterials for preventing and treating various common radiation‐induced diseases. Furthermore, the sources, clinica l symptoms, and pathogenesis/injury mechanisms of these radiation‐induced diseases will also be introduced. Furthermore, current challenges and directions for future efforts in this field are also discussed. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Interactions between Biomedical Micro‐/Nano‐Motors and the Immune Molecules, Immune Cells, and the Immune System: Challenges and Opportunities

xloma.fota13 shared this article with you from Inoreader Interactions between Biomedical Micro‐/Nano‐Motors and the Immune Molecules, Immune Cells, and the Immune System: Challenges and Opportunities Via Advanced Healthcare Materials Versatile micro‐/nano‐motors (MNMs) are potential tools in the field of biomedicine. Unveiling the interplay of MNMs with the immune system is significant. This report elucidates from two perspectives based on recent research progress. One is focused on immune‐related barriers and strategies to overcome. While the other is about the applications of MNMs that join forces with the immune components. Abstract Mobile micro‐ and nano‐motors (MNMs) emerge as revolutionary platforms for biomedical applications, including drug delivery, biosensing, non‐invasive surgery, and cancer therapy. While for applications in biomedical fields and practical clinical translation, the interactions of these untethered tiny machines with the immune system is an essential issue to be considered. This review highlights the recent approaches of surpassing immune barriers to prevent foreign motors from triggering immune responses. In addition to trials focusing on the function preservation of MNMs, examples of versatile MNMs working with the immune components (immune molecules, immune cells and the whole system) to achieve cancer immunotherapy, immunoassay, and detoxification are outlined. The immune interference part provides researchers an idea about what is the limit presented by the immune components. The coworking part suggests ways to bypass or even utilize the limit. With interdisciplinary cooper ation of nanoengineering, materials science, and immunology field, the rationally designed functional MNMs are expected to provide novel opportunities for the biomedical field. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

Functionalized Elastomers for Intrinsically Soft and Biointegrated Electronics

xloma.fota13 shared this article with you from Inoreader Functionalized Elastomers for Intrinsically Soft and Biointegrated Electronics Via Advanced Healthcare Materials Elastomers are highly beneficial for developing intrinsically soft and biointegrated electronics owing to the ease in their functionalization using conducting/semiconducting filler materials to acquire desired electrical properties, and owing to their tunable mechanical properties to match their moduli to those of target tissues for minimization of the interface mismatch. Functionalization of elastomers toward intrinsically soft and biointegrated electronics is reviewed. Abstract Elastomers are suitable materials for constructing a conformal interface with soft and curvilinear biological tissue due to their intrinsically deformable mechanical properties. Intrinsically soft electronic devices whose mechanical properties are comparable to human tissue can be fabricated using suitably functionalized elastomers. This article reviews recent progress in functionalized elastomers and their application to intrinsically soft and biointegrated electronics. Elastomers can be functionalized by adding appropriate fillers, either nanoscale materials or polymers. Conducting or semiconducting elastomers synthesized and/or processed with these materials can be applied to the fabrication of soft biointegrated electronic devices. For facile integration of soft electronics with the human body, additional functionalization strategies can be employed to improve adhesive or autonomous healing properties. Recently, device components for intrinsically soft and biointegrated electr onics, including sensors, stimulators, power supply devices, displays, and transistors, have been developed. Herein, representative examples of these fully elastomeric device components are discussed. Finally, the remaining challenges and future outlooks for the field are presented. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

siRNA Therapeutics against Respiratory Viral Infections—What Have We Learned for Potential COVID‐19 Therapies?

xloma.fota13 shared this article with you from Inoreader siRNA Therapeutics against Respiratory Viral Infections—What Have We Learned for Potential COVID‐19 Therapies? Via Advanced Healthcare Materials Pulmonary delivery of siRNA holds great promise for inhibiting respiratory virus replication particularly when antiviral drugs and vaccines are not yet available. This progress report discusses previous attempts of silencing respiratory viruses by highlighting the choice of target gene regions, the opportunities for the field of siRNA delivery and challenges in the development of inhalable siRNA formulations, particularly against SARS‐CoV‐2. Abstract Acute viral respiratory tract infections (AVRIs) are a major burden on human health and global economy and amongst the top five causes of death worldwide resulting in an estimated 3.9 million lives lost every year. In addition, new emerging respiratory viruses regularly cause outbreaks such as SARS‐CoV‐1 in 2003, the "Swine flu" in 2009, or most importantly the ongoing SARS‐CoV‐2 pandemic, which intensely impact global health, social life, and economy. Despite the prevalence of AVRIs and an urgent need, no vaccines—except for influenza—or effective treatments were available at the beginning of the COVID‐19 pandemic. However, the innate RNAi pathway offers the ability to develop nucleic acid‐based antiviral drugs. siRNA sequences against conserved, essential regions of the viral genome can prevent viral replication. In addition, viral infection can be averted prophylactically by silencing host genes essential for host–viral interactions. Unfortunately, delivering siRNAs to their target cells and intracellular site of action remains the principle hurdle toward their therapeutic use. Currently, siRNA formulations and chemical modifications are evaluated for their delivery. This progress report discusses the selection of antiviral siRNA sequences, delivery techniques to the infection sites, and provides an overview of antiviral siRNAs against respiratory viruses. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.

A Magnetically Guided Self‐Rolled Microrobot for Targeted Drug Delivery, Real‐Time X‐Ray Imaging, and Microrobot Retrieval

xloma.fota13 shared this article with you from Inoreader A Magnetically Guided Self‐Rolled Microrobot for Targeted Drug Delivery, Real‐Time X‐Ray Imaging, and Microrobot Retrieval Via Advanced Healthcare Materials A magnetically guided self‐rolled microrobot is developed for targeted drug delivery. The self‐rolled microrobot is capable of loading anticancer drug and X‐ray contrast agent using its structural property. The microrobot can perform precise targeting through autonomous driving under X‐ray imaging and rapidly release drugs through near‐infrared stimulus. After drug delivery, the microrobot can be safely recovered using magnetic field generators. Abstract Targeted drug delivery using a microrobot is a promising technique capable of overcoming the limitations of conventional chemotherapy that relies on body circulation. However, most studies of microrobots used for drug delivery have only demonstrated simple mobility rather than precise targeting methods and prove the possibility of biodegradation of implanted microrobots after drug delivery. In this study, magnetically guided self‐rolled microrobot that enables autonomous navigation‐based targeted drug delivery, real‐time X‐ray imaging, and microrobot retrieval is proposed. The microrobot, composed of a self‐rolled body that is printed using focused light and a surface with magnetic nanoparticles attached, demonstrates the loading of doxorubicin and an X‐ray contrast agent for cancer therapy and X‐ray imaging. The microrobot is precisely mobilized to the lesion site through automated targeting using magnetic field control of an electromagnetic actuation system under r eal‐time X‐ray imaging. The photothermal effect using near‐infrared light reveals rapid drug release of the microrobot located at the lesion site. After drug delivery, the microrobot is recovered without potential toxicity by implantation or degradation using a magnetic‐field‐switchable coiled catheter. This microrobotic approach using automated control method of the therapeutic agents‐loaded microrobot has potential use in precise localized drug delivery systems. View on the web Inoreader. Take back control of your news feed. Follow us on Twitter and Facebook.