Matthew W. Kemp’s research while affiliated with Chongqing Medical University and other places

Introduction: A single course of antenatal steroid (ANS) therapy is standard of care for women at risk of preterm birth, reducing the risk of neonatal respiratory distress syndrome, neonatal morbidity and mortality. An unresolved challenge relates to the potential risk for adverse long-term effects, and how these risks might be balanced with therapeutic benefit. Areas covered: We outline key concepts in glucocorticoid signaling, pharmacokinetics/pharmacodynamics, and clinical use before presenting data on the potential long-term harms of ANS therapy. Expert opinion: Our assessment is i) Currently used, high dose ANS regimens can induce multi-system changes in the fetus that alter growth and development, potentially increasing long-term disease risk; ii) relative risks likely increase proportionally to the magnitude and duration of steroid exposure, in late preterm and term ANS use, and in off-target treatments. A single course of ANS therapy to at risk women between 24- and 34-weeks' gestation is well justified. Efforts should be made to improve dosing and patient selection. At periviable gestations the high immediate risk of serious disease or death justifies modest long-term risks. At late preterm and term gestations, where steroids do not provide significant survival or health benefits, supporting routine ANS use is more difficult. Keywords: Antenatal steroids; HPA axis; adverse effects; cardiovascular; development; fetal; growth restriction; hepatic; neurodevelopment; on and off target; preterm birth; programming; renal.

Intrauterine inflammation is a significant cause of early preterm birth and fetal injury. There is a lack of effective interventions for intrauterine inflammation. This study aimed to determine whether direct fetal treatment with IL-1 receptor antagonists (IL-1RA), specifically anakinra (competitive IL-1RA) or rytvela (allosteric IL-1RA), could reduce intrauterine inflammation caused by intraamniotic injection of E. coli lipopolysaccharides (LPS) in a sheep model of pregnancy. We hypothesized the fetal intramuscular administration of IL1-RA therapy would comprehensively resolve intrauterine inflammation caused by LPS in the pregnant sheep model. Date-mated Merino ewes carrying single fetuses were randomized into four groups: LPS Group (10 mg intraamniotic LPS injection followed by saline), RYTVELA Group (10 mg LPS injection followed by 5 mg rytvela), ANAKINRA Group (LPS injection followed by 100 mg anakinra), and SALINE Group (saline injection followed by saline). All LPS-exposed fetuses had elevated bilirubin levels, leukopenia, and increased inflammatory mediators IL-1β, IL-8, tumour necrosis factor alpha (TNFα), and monocyte chemoattractant protein 1 (MCP-1) in amniotic fluid and lung tissue. Both anakinra and rytvela treatments reduced immunocyte infiltration in chorioamniotic membranes and lungs, and microglial staining, and increased the oligodendrocyte staining, but did not significantly resolve overall inflammation compared to the SALINE Group. In conclusion, fetal intramuscular administration of anakinra and rytvela did not effectively resolve intrauterine inflammation but showed potential in reducing tissue invasion and brain injury markers. These findings suggest that modest inflammation reduction may protect against brain injury and preterm birth, though no additional benefit was observed compared to intraamniotic IL-1RA treatment.

Background Antenatal steroid (ANS) therapy is given to women at risk of preterm delivery to accelerate fetal lung maturation. However, the benefit of ANS therapy is variable and how maternal and fetal factors contribute to this observed variability is unknown. We aimed to test the degree of concordance in preterm lung function, and correlate this with genomic, transcriptomic, and pharmacokinetic variables in preterm dizygotic twin ovine fetuses. Methods Thirty-one date-mated ewes carrying twin fetuses at 123 ± 1 days’ gestation received maternal intramuscular injections of either (i) 1 × 0.25 mg/kg betamethasone phosphate and acetate (CS1, n = 11 twin pairs) or (ii) 2 × 0.25 mg/kg betamethasone phosphate and acetate, 24 h apart (CS2, n = 10 twin pairs) or (iii) 2 × saline, 24 h apart (negative control, n = 10 twin pairs). Fetuses were surgically delivered 24 h after their final treatment and ventilated for 30 min. Results ANS-exposed female fetuses had lower arterial partial pressure of carbon dioxide (PaCO2) values than male fetuses (76.5 ± 38.0 vs. 97.2 ± 42.5 mmHg), although the observed difference was not statistically significant (p = 0.1). Only 52% of ANS-treated twins were concordant for lung maturation responses. There was no difference in fetal lung tissue or plasma steroid concentrations within or between twin pairs. Genomic analysis identified 13 single-nucleotide polymorphisms (SNPs) statistically associated with ANS-responsiveness, including in the proto-oncogene MET and the transcription activator STAT1. Conclusions Twin fetal responses and ANS tissue levels were comparable with those from singleton fetuses in earlier studies. Twin ovine fetuses thus benefit from ANS in a similar manner to singleton fetuses, and a larger dose of betamethasone is not required. Assuming no difference in input from the placental or maternal compartments, fetal lung responses to ANS therapy in dizygotic twin preterm lambs are dependent on the fetus itself. These data suggest a potential heritable role in determining ANS responsiveness.

Aim To characterize the gingival crevicular fluid (GCF) and plasma extracellular vesicles (EVs) and explore their proteomic cargo in healthy pregnant women compared to those with gestational diabetes mellitus (GDM) and periodontitis. Methods One‐hundred and four pregnant women were recruited at 24–30 gestation weeks. GDM was diagnosed by an oral glucose tolerance test. GCF and plasma samples were obtained to isolate EVs and characterized by nanoparticle tracking, immunoassays, electron microscopy and mass spectrometry. Results Of the recruits,17.3% women were healthy, 50% had periodontitis and 32.7% had both GDM and periodontitis. Probing depth, clinical attachment loss and bleeding on probing were more severe in GDM and periodontitis pregnancies ( p < 0.0001). Additionally, this group showed an increase concentration of total, small and large GCF‐EVs ( p = 0.0015, p = 0.0011 and p = 0.0008, respectively), with decreased expression of CD9, CD81 and CD81/CD63 ratio ( p = 0.0461, p = 0.0164 and p = 0.0005, respectively). No differences were observed in plasmatic EVs concentration or markers expression. Proteomic analysis of GCF‐EVs showed peptides of both host and bacterial origin. Gene ontology analysis revealed that proteins of GCF‐EVs participate in immune inflammatory responses, glucose metabolism and insulin response mechanisms. Conclusion GCF‐EVs were increased in both GDM and periodontitis, and their proteomic cargo suggest their involvement in immune inflammatory response, glucose metabolism and insulin pathways during pregnancy.

Background Antenatal steroid therapy for fetal lung maturation is routinely administered to women at risk of preterm delivery. There is strong evidence to demonstrate benefit from antenatal steroids in terms of survival and respiratory disease, notably in infants delivered at or below 32 weeks’ gestation. However, dosing remains unoptimized and lung benefits are highly variable. Current treatment regimens generate high-concentration, pulsatile fetal steroid exposures now associated with increased risk of childhood neurodevelopmental diseases. We hypothesized that damage-associated changes in the fetal hippocampal transcriptome would be independent of preterm lung function. Methods Date-mated ewes carrying a single fetus at 122 ± 2dGA (term = 150dGA) were randomized into 4 groups: (i) Saline Control Group, 4×2ml maternal saline intramuscular(IM) injections at 12hr intervals (n = 11); or (ii) Dex High Group, 2×12mg maternal IM dexamethasone phosphate injections at 12hr intervals followed by 2×2ml IM saline injections at 12hr intervals (n = 12; representing a clinical regimen used in Singapore); or (iii) Dex Low Group, 4×1.5mg maternal IM dexamethasone phosphate injections 12hr intervals (n = 12); or (iv) Beta-Acetate Group, 1×0.125mg/kg maternal IM betamethasone acetate injection followed by 3×2ml IM sterile normal saline injections 12hr intervals (n = 8). Lambs were surgically delivered 48hr after first maternal injection at 122–125dGA, ventilated for 30min to establish lung function, and euthanised for necropsy and tissue collection. Results Preterm lambs from the Dex Low and Beta-Acetate Groups had statistically and biologically significant lung function improvements (measured by gas exchange, lung compliance). Compared to the Saline Control Group, hippocampal transcriptomic data identified 879 differentially significant expressed genes (at least 1.5-fold change and FDR < 5%) in the steroid-treated groups. Pulsatile dexamethasone-only exposed groups (Dex High and Dex Low) had three common positively enriched differentially expressed pathways related in part to neurodegeneration (“Prion Disease”, “Alzheimer’s Disease”, “Arachidonic Acid metabolism”). Adverse changes were independent of respiratory function during ventilation. Conclusions Our data suggests that exposure to antenatal steroid therapy is an independent cause of damage- associated transcriptomic changes in the brain of preterm, fetal sheep. These data highlight an urgent need for careful reconsideration and balancing of how antenatal steroids are used, both for patient selection and dosing regimens.

Human Wharton’s jelly stem cells (hWJSCs) are multipotent stem cells that are extensively employed in biotechnology applications. However, the impact of simulated lunar microgravity (sμG) on the growth, differentiation, and viability of this cell population is incompletely characterized. We aimed to determine whether acute (72 h) exposure to sμG elicited changes in growth and lineage differentiation in hWJSCs and if putative changes were maintained once exposure to terrestrial gravity (1.0 G) was restored. hWJSCs were cultured under standard 1.0 G conditions prior to being passaged and cultured under sμG (0.16 G) using a random positioning machine. Relative to control, hWJSCs cultured under sμG exhibited marked reductions in growth but not viability. Cell population expression of characteristic stemness markers (CD 73, 90, 105) was significantly reduced under sμG conditions. hWJSCs had 308 significantly upregulated and 328 significantly downregulated genes when compared to 1.0 G culture conditions. Key markers of cell replication, including MKI67 , were inhibited. Significant upregulation of osteocyte–chondrocyte lineage markers, including SERPINI1, MSX2, TFPI2, BMP6, COMP, TMEM119, LUM, HGF, CHI3L1 and SPP1 , and downregulation of cell fate regulators, including DNMT1 and EZH2 , were detected in sμG-exposed hWJSCs. When returned to 1.0 G for 3 days, sμG-exposed hWJSCs had accelerated growth, and expression of stemness markers increased, approaching normal (i.e. 95%) levels. Our data support earlier findings that acute sμG significantly reduces the cell division potential of hWJSCs and suggest that acute sμG-exposure induces reversible changes in cell growth accompanied by osteocyte–chondrocyte changes in lineage differentiation.

Background: A combination of budesonide and surfactant decreases the rates of BPD in infants and lung injury in preterm sheep. Whether this combination will show benefit in the setting of chorioamnionitis and antenatal steroids is not known. Methods: Ewes at 123 ± 1 day gestational age received intra-amniotic (IA) injections of 10 mg LPS before being randomized to receive either 0.25 mg/kg maternal betamethasone phosphate and acetate or saline by intramuscular (IM) injection at 48 and 24 h prior to delivery at 125 ± 1 day. Lambs (N = 6-9/group) underwent intentionally injurious ventilation for 15 min, then lambs received surfactant mixed with either: (1) saline; or (2) Budesonide 0.25 mg/kg and were ventilated for 4 h. Results: Compared with LPS-exposed animals that received no IM steroid treatment, betamethasone exposed fetuses had improved hemodynamic stability, lung compliance, and ventilation efficiency. The addition of budesonide to surfactant further improved markers of injury and pro-inflammatory cytokine mRNA in both betamethasone IM or no IM lambs exposed to LPS IA. Antenatal betamethasone and IA LPS exposures decreased budesonide levels in the fetal lung and plasma. Conclusion: Antenatal betamethasone stabilizes physiologic parameters in LPS treated lambs. Budesonide mixed with surfactant further decreases injury and improves respiratory physiology in betamethasone treated animals. Impact: Antenatal betamethasone improved lung and systemic physiology in the setting of intra-amniotic LPS. The addition of budesonide to the surfactant further improved lung function. Budesonide levels in the plasma and lung were lower in lambs exposed to either LPS or LPS and Betamethasone animals, and these findings were not explained by increased esterification in the lungs. The combination of antenatal steroids and budesonide with surfactant had the lowest markers of pro-inflammatory cytokines in the lung of LPS exposed animals.

Objective Extremely preterm infants have low Nuclear Receptor (NR) expression in their developing hepatobiliary systems, as they rely on the placenta and maternal liver for compensation. NRs play a crucial role in detoxification and the elimination of both endogenous and xenobiotic substances by regulating key genes encoding specific proteins. In this study, we utilized an Artificial Placenta Therapy (APT) platform to examine the liver tissue expression of NRs of extremely preterm ovine fetuses. This fetal model, resembling a “knockout placenta,” lacks placental and maternal support, while maintaining a healthy extrauterine survival. Methods Six ovine fetuses at 95 ± 1 d gestational age (GA; term = ∼150 d)/∼600 g delivery weight were maintained on an APT platform for a period of 120 h (APT Group). Six age-matched, in utero control fetuses were delivered at 99–100 d GA (Control Group). Fetal liver tissue samples and blood samples were collected at delivery from both groups and assessed mRNA expression of NRs and target transporters involved in the hepatobiliary transport system using quantitative PCR. Data were tested for group differences with ANOVA (p < .05 deemed significant). Results mRNA expression of NRs was identified in both the placenta and the extremely preterm ovine fetal liver. The expression of HNF4α, LRH1, LXR, ESR1, PXR, CAR, and PPARα/γ were significantly elevated in the liver of the APT Group compared to the Control Group. Moreover, target transporters NTCP, OATP1B3, BSEP, and MRP4 were upregulated, whereas MRP2 and MRP3 were unchanged. Although there was no evidence of liver necrosis or apoptotic changes histologically, there was an impact in the fetal liver of the ATP group at the tissue level with a significant increase in TNFα mRNA, a cytokine involved in liver inflammation, and blood elevation of transaminases. Conclusion A number of NRs in the fetal liver were significantly upregulated after loss of placental-maternal support. However, the expression of target transporter genes appeared to be insufficient to compensate role of the placenta and maternal liver and avoid fetal liver damage, potentially due to insufficient excretion of organic anions.