Psychological consequences of experiencing the COVID-19 coronavirus pandemic: early maladaptive schemas and mental health and quality of life.

The research presented here aimed to determine the psychological consequences of experiencing Poland's coronavirus disease 2019 (COVID-19) pandemic. We focused on changes in mental health (anxiety and depression symptoms, morbid thoughts, and suicidal ideation) and quality of life. Our retrospective study included 499 adults comprising 316 women and 173 men (aged 18-72, Me = 27, SD = 12.48). We employed the following research tools: the General Health Questionnaire (GHQ-30), the shortened version of the World Health Organization Quality of Life Questionnaire (WHOQOL-BREF), and the abridged version of the Harkavy Asnis Suicide Survey (HASS-BREF) scale to assess the severity of suicidal ideations and behaviors, as well as the Young Schema Questionnaire (YSQ-S3-PL). The questionnaires' instructions for the subjects were modified to obtain information for three specific periods: before the pandemic, at the most difficult time of the pandemic for individuals, and in the last two weeks (the time period preceding data collection; January/February 2021). It emerged that both mental health and quality of life had deteriorated significantly in the studied population. In addition, early maladaptive schemas (Abandonment, Vulnerability to Harm, and Insufficient Self-Control) were likely predictors of mental health deterioration at the most difficult time of the COVID-19 pandemic. The schema of Defectiveness was likely predictor of a lower severity of symptoms of mental health disturbances. If psychological diagnosis covered the identification of thinking patterns typical of maladaptive schemas, which may be a risk factor for mental health deterioration, psychologists could better adapt forms and ways of psychological assistance to the patient's needs.

Bioactive Nanofiber-Based Conduits in a Peripheral Nerve Gap Management-An Animal Model Study.

The aim was to examine the efficiency of a scaffold made of poly (L-lactic acid)-co-poly(ϵ-caprolactone), collagen (COL), polyaniline (PANI), and enriched with adipose-derived stem cells (ASCs) as a nerve conduit in a rat model. P(LLA-CL)-COL-PANI scaffold was optimized and electrospun into a tubular-shaped structure. Adipose tissue from 10 Lewis rats was harvested for ASCs culture. A total of 28 inbred male Lewis rats underwent sciatic nerve transection and excision of a 10 mm nerve trunk fragment. In Group A, the nerve gap remained untouched; in Group B, an excised trunk was used as an autograft; in Group C, nerve stumps were secured with P(LLA-CL)-COL-PANI conduit; in Group D, P(LLA-CL)-COL-PANI conduit was enriched with ASCs. After 6 months of observation, rats were sacrificed. Gastrocnemius muscles and sciatic nerves were harvested for weight, histology analysis, and nerve fiber count analyses. Group A showed advanced atrophy of the muscle, and each intervention (B, C, D) prevented muscle mass decrease (p < 0.0001); however, ASCs addition decreased efficiency vs. autograft (p < 0.05). Nerve fiber count revealed a superior effect in the nerve fiber density observed in the groups with the use of conduit (D vs. B p < 0.0001, C vs. B p < 0.001). P(LLA-CL)-COL-PANI conduits with ASCs showed promising results in managing nerve gap by decreasing muscle atrophy.

Evaluation of the biocompatibility of fish skin collagen with the mesenchymal stem cells in in vitro cultures.

There are scarce published data suggesting, that collagen extracted from fish skin may be an attractive alternative to mammalian-derived collagen for the in vitro cell cultures. In this study, we investigated proliferation potential and differentiation capability into osteogenic and adipogenic lineages of rat adipose-derived mesenchymal stem cells (rASCs) and human adipose-derived mesenchymal stem cells (hASCs) cultured on collagen extracted from silver carp and African sharptooth catfish skins, compared with commercially available mammalian collagen and collagen-free culture dishes. Our results revealed no significant differences between fish collagen and mammalian collagen in supporting cell viability and proliferation capacity. Fish-derived collagen is a cheap material derived from production waste, does not contain transmissible pathogens of mammalian origin, supports human cell cultures at comparable level to conventional collagen sources, and may be considered as the product of choice for the in vitro cell cultures.

The impact of electroconductive multifunctional composite nanofibrous scaffold on adipose-derived mesenchymal stem cells.

BACKGROUND: The development of tissue-engineered scaffolds with electrical properties is the primary motivation of novel regenerative medicine. Electroconductive scaffolds are designed to mimic the injured tissue environment's electrical properties and regulate cellular behavior - growth, proliferation, and differentiation - that could stimulate the injured nerve's regeneration. METHODS: We fabricated dedicated electroconductive scaffolds and customized an appropriate device with an external current supply to expose cells on the scaffold to electrical stimulation (ES). Next, we isolated rat adipose-derived stem cells (ASCs) and performed in vitro experiments that combine cells, an electroconductive scaffold, NGF (nerve growth factor), and ES (90 mV/mm, constant, for four days). Finally, we checked cellular activity as proliferation, viability, morphology, the neurogenic differentiation potential of ASCs, cell alignment, and karyotype. RESULTS: We observed that the electrical stimulation did not change the viability and chromosome stability of rat ASCs, but altered slightly proliferation compared to non-stimulated cells. The combined effect of a scaffold, NGF, and ES caused morphology changes and enhancement of ASCs neuronal differentiation as indicated in ßIII-tubulin expression, actin organization, and upregulation of neurogenic gene expression. CONCLUSIONS: We developed an electroconductive scaffold and customized device for in vitro study with many experimental variants. Based on our results, we presumed that the established study scheme - including an electroconductive scaffold, NGF and ES - is biocompatible and could guide ASCs to differentiate in neurogenic lineage, thus may be potentially applied in nerve injury regeneration.

Neurogenesis Using P19 Embryonal Carcinoma Cells.

The P19 cell line derived from a mouse embryo-derived teratocarcinoma has the ability to differentiate into the three germ layers. In the presence of retinoic acid (RA), the suspension cultured P19 cell line is induced to differentiate into neurons. This phenomenon is extensively investigated as a neurogenesis model in vitro. Therefore, the P19 cell line is very useful for molecular and cellular studies associated with neurogenesis. However, protocols for neuronal differentiation of P19 cell line described in the literature are very complex. The method developed in this study are simple and will play a part in elucidating the molecular mechanisms in neurodevelopmental abnormalities and neurodegenerative diseases.

Adipose-Derived Cells (Stromal Vascular Fraction) Transplanted for Orthopedical or Neurological Purposes: Are They Safe Enough?

Although mesenchymal stem cells are used in numerous clinical trials, the safety of their application is still a matter of concern. We have analysed the clinical results of the autologous adipose-derived stem cell treatment (stromal vascular fraction (SVF) containing adipose-derived stem cells, endothelial progenitors, and blood mononuclear cells) for orthopedic (cartilage, bone, tendon, or combined joint injuries) and neurologic (multiple sclerosis) diseases. Methods of adipose tissue collection, cell isolation and purification, and resulting cell numbers, viability, and morphology were considered, and patient's age, sex, disease type, and method of cell administration (cell numbers per single application, treatment numbers and frequency, and methods of cell implantation) were analysed and searched for the unwanted clinical effects. Results of cellular therapy were compared retrospectively to those obtained with conventional medication without SVF application. SVF transplantation was always the accessory treatment of patients receiving "standard routine" therapies of their diseases. Clinical experiments were approved by the Bioethical Medical Committees supervising the centers where patients were hospitalised. The conclusion of the study is that none of the treated patients developed any serious adverse event, and autologous mesenchymal stem (stromal) cell clinical application is a safe procedure resulting in some beneficial clinical effects (not analysed in this study).