PVP - CMC hydrogel: An excellent bioinspired and biocompatible scaffold for osseointegration

Fabrication of porous and biologically inspired biomaterials that mimic the formation of microstructural structures of nacre in the form of calcite (CaCO3) and evaluation of the biocompatibility of such organic-inorganic composite scaffold for bone tissue engineering, are focus of this paper. Nacre's self-assembly characteristics are concerned about the development of calcite filled biomineralized scaffold following the nature based biomineralization process and biomimetic applications. The PVP-CMC hydrogel film, comprised of PVP:0.2, CMC:0.8, PEG:1.0, Agar:2.0, Glycerene:1.0 and water:95.0 w/v%; acts as catalyst and template for the nucleation and growth of the inorganic CaCO3 within the scaffold. The PVP-CMC hydrogel (in the dry state) was immersed in ionic solutions (g/100 ml) of Na2CO3 and CaCl2·H2O in different concentrations sets i.e. Set-1: 10.50/14.70; Set-2: 5.25/7.35; Set-3: 4.20/5.88; Set-4: 2.10/2.94; Set-5: 1.05/1.47, Set-6: 0.55/0.55 for 90 min. As a result, “PVP-CMC-CaCO3” hydrogel scaffold was fabricated having bio-inspired structural and functional properties. Cell proliferation and cell viability were examined until 7 days in the presence of “PVP-CMC-CaCO3” scaffolds using permanent cell lines MG63 (human osteosarcoma), L929 (murine fibroblasts) as well as cultures from mouse bone explants (CC-MBE), confirmed that the said hydrogel scaffolds are biocompatible. But, from mechanical strength as well as biocompatibility point of view, scaffolds prepared in Set-1 to 3 ionic solutions were superior. In conclusion, these three calcite filled hydrogel scaffolds are recommended and can be used for osseointegration. © 2018 Elsevier B.V.Tomas Bata University in Zlin [IGA/FT/2014/015]; Ministry of Education, Youth and Sports of the Czech Republic-Program NPUI [LO1504]; Fund "Scientific Research", Bulgarian Ministry of Education and Science [(sic)02-30/2014]; Department of Biotechnology (DBT); Department of Science and Technology (DST), Government of India; COST Action [MP1301

A NEW GASTRIC-JUICE PEPTIDE, BPC - AN OVERVIEW OF THE STOMACH-STRESS-ORGANOPROTECTION HYPOTHESIS AND BENEFICIAL-EFFECTS OF BPC

The possibility that the stomach, affected by general stress, might initiate a counter-response has not until recently been considered in theories of stress. We suggest that the stomach, as the most sensitive part of the gastrointestinal tract and the largest neuroendocrine organ in the body, is crucial for the initiation of a full stress response against all noxious stress pathology. The end result would be a strong protection of all organs invaded by 'stress'. Consistent with this assumption, this coping response is best explained in terms of 'organoprotection'. Endogenous organoprotectors (eg prostaglandins, somatostatin, dopamine) are proposed as mediators. Such an endogenous counteraction could even be afforded by their suitable application. A new gastric juice peptide, M(r) 40,000, named BPC, was recently isolated. Herein, a 15 amino acid fragment (BPC 157), thought to be essential for its activity, has been fully characterized and investigated. As has been demonstrated for many organoprotective agents using different models of various tissue lesions, despite the poorly understood final mechanism, practically all organ systems appear to benefit from BPC activity. These effects have been achieved in many species using very low dosages (mostly microgram and ng/kg range) after ip, ig, and intramucosal (local) application. The effect was apparent already after one application. Long lasting activity was also demonstrated. BPC was highly effective when applied simultaneously with noxious agents or in already pathological, as well as chronical, conditions. Therefore, it seems that BPC treatment does not share any of the so far known limitations for 'conventional organoprotectors'. No influence on different basal parameters and no toxicity were observed. These findings provide a breakthrough in stress theory. BPC, as a possible endogenous free radical scavenger and organoprotection mediator, could be a useful prototype of a new class of drugs, organoprotective agents

Interaction between epsomite crystals and organic additives

A number of phosphonates and carboxylates were tested as potential crystallization inhibitors for epsomite (MgSO4·7H 2O). Epsomite nucleation is strongly inhibited in the presence of amino tri(methylene phosphonic acid) (ATMP), diethylenetriaminepentakis (methylphosphonic acid) (DTPMP), and poly(acrylic acid) sodium salt (PA). These additives also act as habit modifiers promoting the growth of acicular crystals elongated along the [001] direction. Environmental scanning electron microscopy (ESEM), Fourier transform infrared spectroscopy (FTIR), atomic force microscopy (AFM), and molecular modeling of additive adsorption on specific epsomite (hkl) faces are used to identify how these additives inhibit epsomite crystallization. Additives attach preferentially on epsomite {110} faces, at edges of monolayer steps parallel to [001]. Step pinning and the eventual arrest of step propagation along (110) directions account for the observed habit change. Hydrogen bonding between the functional groups of additive molecules and water molecules in epsomite {110} appears to be the principal mechanism of additive-epsomite interaction, as shown by FTIR and molecular modeling. Molecular modeling also shows that DTPMP displays a high stereochemical matching with epsomite {110} surfaces, which can explain why this is the most effective inhibitor tested. The use of such effective crystallization inhibitors may lead to more efficient preventive conservation of ornamental stone affected by epsomite crystallization damage. © 2008 American Chemical Society