Biostimulating fillers and induction of inflammatory pathways: A preclinical investigation of macrophage response to calcium hydroxylapatite and poly-L lactic acid.

INTRODUCTION: Initial macrophage response to biostimulatory substances is key in determining the subsequent behavior of fibroblasts and the organization of newly synthesized collagen. Though histological studies suggest that calcium hydroxylapatite (CaHA) filler initiates a regenerative healing response with collagen and elastin deposition similar to natural, healthy tissue rather than an inflammatory response with fibrosis, the relative activity of macrophages stimulated by CaHA, as well as how this activity compares to that induced by other biostimulatory fillers, has not been explored. The aim of the study is to characterize the in vitro macrophage response to two biostimulory fillers, CaHA and PLLA (poly-L lactic acid), and to evaluate their inflammatory potential. METHODS: Primary human macrophages were incubated with two dilutions (1:50 and 1:100) of commercially available CaHA or PLLA. After 24 h incubation, an inflammation array was used to screen for the expression of 40 cytokines, released by macrophages. ELISA was used to confirm array results. RESULTS: Four cytokines were significantly upregulated in M1 macrophages incubated with PLLA compared to both unstimulated controls and CaHA: CCL1 (p < 0.001), TNFRII (p < 0.01), MIP-1α (p < 0.05), and IL-8 (p < 0.001). In M2 macrophages, MIP-1α (p < 0.01) and MIP-1ß (p < 0.01) were significantly upregulated by PLLA compared to CaHA and unstimulated controls. CONCLUSION: Together, these findings indicate that the CaHA mode of action is a non-inflammatory response while PLLA initiates expression of several cytokines known to play a role in inflammation. Our study supports the concept that these two "biostimulatory" fillers follow distinct pathways and should be considered individually with regard to mechanism of action.

Comparison of Physicochemical Characteristics and Biostimulatory Functions in Two Calcium Hydroxyapatite-Based Dermal Fillers.

BACKGROUND:   Dermal fillers containing calcium hydroxyapatite (CaHA) are categorized as biostimulatory. However, differences in CaHA biomaterial likely affect the resultant induction of collagen synthesis, and variability in microsphere shape and size likely influences a patient’s immune response. This study compares 2 CaHA based fillers: one suspended in carboxymethylcellulose (denoted "CaHA/CMC"), and one crosslinked with 1,4-butanediol diglycidyl ether to hyaluronic acid (denoted "CaHA/HA"). OBJECTIVE: To characterize CaHA/CMC and CaHA/HA fillers to stimulate in vitro collagen biosynthesis. METHODS: Physicochemical evaluations included G′ and extrusion force. Scanning electron microscopy (SEM) was used to characterize isolated CaHA microspheres and freeze-dried formulations. Collagen I and III expression were evaluated using immunofluorescence. RESULTS: CaHA/CMC showed higher G′ (P<0.001) and lower extrusion force (P=0.0003), with uniform polymeric-matrix interactions, compared with CaHA/HA. On SEM, isolated microspheres and freeze-dried CaHA/CMC showed round and smooth surfaced microspheres of similar size. Isolated microspheres and freeze-dried CaHA/HA showed nonhomogeneous, broken microspheres, of various sizes, with fragments embedded in the polymer matrix. Although both fillers induced collagen III expression, only CaHA/CMC induced longer-lasting collagen I expression, with increases of 123% (P=0.007) and 164% (P<0.0001) at 2 and 5 mg/mL, respectively, compared with control. CaHA/CMC also increased collagen I expression at equivalent CaHA microsphere concentrations at 2 (P=0.0052) and 5 mg/mL (P<0.0001), compared with CaHA/HA. CONCLUSION: The physicochemical characteristics selected for evaluation were more favorable for CaHA/CMC than CaHA/HA. When compared with CaHA/HA, the smooth, homogeneous microsphere composition of CaHA/CMC promoted significantly more collagen I biosynthesis, an essential process for tissue augmentation and long-lasting aesthetic improvement. Citation: Kunzler C, Hartmann C, Nowag B, et al. Comparison of physicochemical characteristics and biostimulatory functions in two calcium hydroxyapatite-based dermal fillers. J Drugs Dermatol. 2023;22(9):910-916. doi:10.36849/JDD.7684.

Calcium hydroxylapatite microspheres activate fibroblasts through direct contact to stimulate neocollagenesis.

BACKGROUND: Calcium hydroxylapatite (CaHA; Radiesse, Merz North America) restores volume and stimulates collagen production. The aim of this research was to explore the role of dilution and diffusion in microsphere distribution and the effect of CaHA concentration on activation of fibroblasts to produce collagen. METHODS: Ex vivo: Tissue dispersion of CaHA was assessed in abdominal tissue segments obtained from patients which were subsequently injected with CaHA diluted to 1:1 and hyperdiluted to 1:2. In vitro: Collagen type III (COLIII) and type I (COLI) expression of fibroblasts was evaluated after 24 and 72 h of incubation with CaHA concentrations of 1.5 (high dilution), 3.0, and 4.5 mg/ml (low dilution). RESULTS: Ex vivo: The 1:2 CaHA hyperdilution increased dispersion and decreased concentration of CaHA microspheres compared with the 1:1 dilution. In vitro: CaHA incubation resulted in an increased mean COLIII expression of 123% at 24 h. COLI synthesis did not change after 24 h but increased up to 124% at 72 h. Only fibroblasts in direct contact with CaHA increased COLIII expression. COLIII high-expressing cells were fully activated by CaHA and resulted in the same level of COLIII expression per cell independent of the CaHA dilution. CONCLUSIONS: A 1:2 hyperdilution of CaHA increased tissue dispersion of CaHA microspheres. Direct contact of CaHA with fibroblasts was a key factor for inducing neocollagenesis. COLIII high-expressing cells were fully activated by CaHA and resulted in the same expression level of COLIII per cell independent of the CaHA amount in each dilution. This indicates that increased collagen expression was due to the activation of more fibroblasts.

Can Sodium Thiosulfate Act as a Reversal Agent for Calcium Hydroxylapatite Filler? Results of a Preclinical Study.

INTRODUCTION: Calcium hydroxylapatite microspheres suspended in a gel carrier of sodium carboxymethylcellulose (CaHA; Radiesse®) has demonstrated safe and effective restoration of facial volume in clinical trials, as well as collagen biostimulation leading to skin quality improvement. The potential with CaHA, as with any filler, to produce overcorrection and subsequent complications has led to the search for a reversal agent. Sodium thiosulfate (STS) was proposed based on experience with it as a chelating agent to treat calciphylaxis. Previous pilot studies with small sample sizes have suggested its efficacy in the reduction of CaHA volume and nodule formation. The present study focuses on the verification of this effect using various readout methods in preclinical experiments. METHODS: We use both in vitro (co-incubation of STS with CaHA) and in vivo (injections in farm pig) methods with readout techniques such as 3D camera analysis, micro-computed tomography ex vivo (µCT), computed tomography in vivo (CT), histopathology and scanning electron microscopy. RESULTS: We did not obtain any indications of CaHA degradation by STS, either in vitro or in vivo. 3D-camera analysis also did not show any decreasing effect of STS on CaHA. However, histology, µCT ex vivo, and CT in vivo indicated a decrease of Radiesse amount/volume after STS treatment, which could be attributed to dispersion effect. It should be noted that necrosis and haemorrhages were observed after STS treatment. DISCUSSION: Results suggest no indication of CaHA microspheres degradation with STS and that the STS mechanism of action on CaHA is consistent with a dispersion effect. Observed necrosis is a further obstacle in the use of STS.