Differential response of human blood leukocytes to brushite, monetite, and calcium polyphosphate biomaterials.

Calcium phosphate-based biomaterials are extensively used for bone replacement and regeneration in orthopedic, dental, and maxillofacial surgical applications. The injury induced by surgical implantation of bone replacement graft materials initiates a cascade of host responses, starting with blood-biomaterial contact, protein adsorption on the material surface, blood coagulation, and leukocyte responses. During the initial acute inflammatory response, polymorphonuclear neutrophils (PMNs) and monocytes, abundant circulating leukocytes of the myeloid lineage, are recruited to the site of inflammation. In addition to responding to pathogenic challenges, these cells respond to particulate substances within the body including crystals of monosodium urate (MSU). Host responses toward grafts impact short- and long-term success in tissue engineering and regenerative applications. Although multinucleated osteoclasts, formed by monocyte/macrophage fusion, are generally thought to be responsible for resorption of implant biomaterials, the ability of different biomaterials to trigger PMNs, which are invariably present at the early stages after implant surgery, and are abundant in the oral cavity, has never been tested. In this article, we present analysis of the response of human blood-derived PMNs and monocytes toward brushite, monetite, and calcium polyphosphate (CPP) biomaterial substrates and compare this to the response to MSU crystals, the latter serving as a positive control. Employing multicolor flow cytometry to look at PMN and monocyte cell surface markers of activation to gauge the response to different biomaterials, we found that both types of myeloid cells are highly activated after exposure to brushite, monetite, and MSU but not CPP. © 2019 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater 108B:253-262, 2020.

Morphological characterization of para- and proinflammatory neutrophil phenotypes using transmission electron microscopy.

BACKGROUND AND OBJECTIVE: Bacterial challenge is constant in the oral cavity. To contain the commensal biofilm, partly activated neutrophils are continuously recruited as part of a normal physiologic process, without exposing the host to the harmful effect of a fully active neutrophil response. This intermediate immune state has been termed para-inflammation, as opposed to the fully activated proinflammatory state in oral disease. Directly visualizing these cells and their components via transmission electron microscopy (TEM) enhances our understanding of neutrophil activation state differences in oral health and disease, as obtained from molecular studies. The aim of this study was to describe the morphology of the para-inflammatory phenotype displayed by oral neutrophils in health, and compare it to the morphology of the naïve blood neutrophil, and the proinflammatory oral neutrophils in chronic periodontitis. This morphology was characterized by differences in granule content, phagosome content and cytoplasm and nuclear changes. We also examined the morphological changes induced in naïve neutrophils, which were stimulated in vitro by bacteria, and in oral neutrophils in full tissue samples in vivo. MATERIAL AND METHODS: Neutrophils were isolated from blood and saliva samples of patients with chronic periodontitis and healthy individuals. The cells were viewed under TEM and analyzed in imaging software examining granularity, cytoplasm density, euchromatin amount in the nucleus and phagosome content. A separate cohort of blood neutrophils was incubated with Streptococcus oralis and analyzed under TEM in the same manner. Gingival tissue samples were obtained from patients with chronic periodontitis and viewed under TEM, with the neutrophils present analyzed in the same manner. RESULTS: The proinflammatory cells showed less granulation, lighter cytoplasm and higher amount of nuclear euchromatin. These changes were accentuated in the proinflammatory oral chronic periodontitis neutrophils compared to the para-inflammatory oral health neutrophils. The oral chronic periodontitis neutrophils also contained more phagosomes and had more phagosomes containing undigested bacteria. These changes were partially reproduced in the naïve blood cells after exposing them to S. oralis. The neutrophils in the gingival tissues displayed naïve morphology when viewed in the blood vessels and gradually showed proinflammatory morphological changes as they traveled through the connective tissue into the epithelium. CONCLUSION: Oral neutrophils display morphological changes consistent with partial or full activation, corresponding to their para- or proinflammatory states. These changes can also be induced in naïve cells by incubating them with commensal bacteria. Neutrophils change their morphology towards an activated state as they travel through the gingival tissue.