Tissue-toxic effects of phosphatidylcholine/deoxycholate after subcutaneous injection for fat dissolution in rats and a human volunteer

Chenodeoxycholic Acid-Loaded Nanoparticles Are Sufficient to Decrease Adipocyte Size by Inducing Mitochondrial Function

Excess fat accumulation is not only associated with metabolic diseases but also negatively impacts physical appearance and emotional well-being. Bile acid, the body's natural emulsifier, is one of the few FDA-approved noninvasive therapeutic options for double chin (submental fat) reduction. Synthetic sodium deoxycholic acid (NaDCA) causes adipose cell lysis; however, its side effects include inflammation, bruising, and necrosis. Therefore, we investigated if an endogenous bile acid, chenodeoxycholic acid (CDCA), a well-known signaling molecule, can be beneficial without many of the untoward effects. We first generated CDCA-loaded nanoparticles to achieve sustained and localized delivery. Then, we injected them into the subcutaneous fat depot and monitored adipocyte size and mitochondrial function. Unlike NaDCA, CDCA did not cause cytolysis. Instead, we demonstrate that a single injection of CDCA-loaded nanoparticles into the subcutaneous fat reduced the adipocyte size by promoting fat burning and mitochondrial respiration, highlighting their potential for submental fat reduction.

The effect of exogenous lipase on subcutaneous adipose tissue in a porcine animal model

BACKGROUND

Topical exogenous lipase has been approved for cosmetic use and has been used to mobilize fat from adipocytes. The objective of this study was to determine the effects of exogenous lipase in the subcutaneous adipose tissue.

METHODS

Three different concentrations of exogenous lipase 1x (2 Units per ml), 5x (10 units per ml), 10x (20 units per ml) were applied in a porcine model. Normal saline (NS) solution (as negative control), and phosphatidylcholine (as positive control) were also injected. Skin and subcutaneous tissue biopsies, up to the fascia, were obtained from each injection site on the 3^rd day after injection. The number of cells per 20x field was counted as an indirect measurement of the size of the adipocytes.

RESULTS

For 1x lipase, the number of cells per field was 47.80 (± 7.63) vs 27.26 (±4.93), and 34.66 (±6.84) for NS, and phosphatidylcholine, respectively. For 5x lipase, the count was 36.06 (±4.74) vs 24.13 (±5.18), and 33.2 (±9.34). For 10x lipase, it was 40.06 (±4.35) vs 29.26 (±2.34) and 32.66 (±6.30) (p<0.05 for all groups).

CONCLUSIONS

A higher number of cells per field were observed in the lipase samples, inferring a decreased volume of adipocytes. No inflammation and/or loss of cell architecture were evidenced in the exogenous lipase groups.

Remodeling of dermal adipose tissue alleviates cutaneous toxicity induced by anti-EGFR therapy

Anti-epidermal growth factor receptor (EGFR) therapy–associated cutaneous toxicity is a syndrome characterized by papulopustular rash, local inflammation, folliculitis, and microbial infection, resulting in a decrease in quality of life and dose interruption. However, no effective clinical intervention is available for this adverse effect. Here, we report the atrophy of dermal white adipose tissue (dWAT), a highly plastic adipose tissue with various skin-specific functions, correlates with rash occurrence and exacerbation in a murine model of EGFR inhibitor-induced rash. The reduction in dWAT is due to the inhibition of adipogenic differentiation by defects in peroxisome proliferator-activated receptor γ (PPARγ) signaling, and increased lipolysis by the induced expression of the lipolytic cytokine IL6. The activation of PPARγ by rosiglitazone maintains adipogenic differentiation and represses the transcription of IL6, eventually improving skin functions and ameliorating the severity of rash without altering the antitumor effects. Thus, activation of PPARγ represents a promising approach to ameliorate cutaneous toxicity in patients with cancer who receive anti-EGFR therapy.

Adverse effects of deoxycholic acid in submandibular glands, submental, inguinal and subplantar regions: a study in rats

OBJECTIVE

We aimed to evaluate the effects of the deoxycholic acid (DCA) in the submental and subplantar regions of rats, and to histologically analyze the changes caused in the submandibular glands, soft tissues of the paw, and inguinal adipose tissue.

MATERIAL AND METHODS

Sixty male Wistar rats were divided into DCA and control (CG) groups. DCA was injected in the submental, inguinal, and subplantar regions, and saline was injected in the CG. The animals were euthanized after 24 h and at 7 and 21 days.

RESULTS

The DCA group showed edema in the submental region in 24 h and in the paw in all experimental times. In the paw there were also erythema and ulceration in 7 days, and alopecia after 21 days. At 21 days, a few animals also showed erythema and ulceration in paw; however, there was no significant difference from CG. Histological analysis of the paw showed an intense inflammatory process, with a predominance of neutrophils, lymphocytes, and plasma cells in 24 h and 7 days. In the adipose tissue, we observed loss of architecture and inflammatory infiltrate, followed with a lower number of adipose cells, and at 21 days, fibroplasia. In the submandibular glands we observed inflammatory infiltration, loss of tissue architecture, and fibrosis.

CONCLUSIONS

DCA produces a significant inflammatory process in the structures. It can cause skin ulcerations and, in salivary glands, it causes loss of tissue architecture and fibrosis.

CLINICAL RELEVANCE

There has been growing increase in the use of DCA for aesthetic purposes by health care providers. Due to the presence of important anatomical structures in the submental region, constant vigilance is required to report new adverse effects.

The Role of Fat Reducing Agents on Adipocyte Death and Adipose Tissue Inflammation

Deoxycholic Acid (DCA), which is an FDA-approved compound for the reduction of submental fat, has evolved through an unanticipated and surprising sequence of events. Initially, it was used as a solvent for Phosphatidylcholine (PDC), which was thought to promote lipolysis, but it was later proven to be the bioactive component of the formula and is currently widely used as Kybella. It has also been used off-label to treat other types of fat deposits like lipomas, HIV lipodystrophy, and excess orbital fat. Despite widespread clinical use, there has been no consensus clarifying the mechanisms of DCA and PDC alone or in combination. Furthermore, despite PDC's removal from the FDA-approved formula, some studies do suggest it plays an important role in fat reduction. To provide some clarity, we conducted a PubMed search and reviewed 41 articles using a comprehensive list of terms in three main categories, using the AND operator: 1) Phosphatidylcholines 2) Deoxycholic Acid, and 3) Lipoma. We isolated articles that studied PDC, DCA, and a PDC/DCA compound using cell biology, molecular and genetic techniques. We divided relevant articles into those that studied these components using histologic techniques and those that utilized specific cell death and lipolysis measurement techniques. Most morphologic studies indicated that PDC/DCA, DCA, and PDC, all induce some type of cell death with accompanying inflammation and fibrosis. Most morphologic studies also suggest that PDC/DCA and DCA alone are non-selective for adipocytes. Biochemical studies describing PDC and DCA alone indicate that DCA acts as a detergent and rapidly induces necrosis while PDC induces TNF-α release, apoptosis, and subsequent enzymatic lipolysis after at least 24 hours. Additional papers have suggested a synergistic effect between the two compounds. Our review integrates the findings of this growing body of literature into a proposed mechanism of fat reduction and provides direction for further studies.

The beneficial effect of glycerophosphocholine to local fat accumulation: a comparative study with phosphatidylcholine and aminophylline

Injection lipolysis or mesotherapy gained popularity for local fat dissolve as an alternative to surgical liposuction. Phosphatidylcholine (PPC) and aminophylline (AMPL) are commonly used compounds for mesotherapy, but their efficacy and safety as lipolytic agents have been controversial. Glycerophosphocholine (GPC) is a choline precursor structurally similar to PPC, and thus introduced in aesthetics as an alternative for PPC. This study aimed to evaluate the effects of GPC on adipocytes differentiation and lipolysis and compared those effects with PPC and AMPL using in vitro and in vivo models. Adipogenesis in 3T3-L1 was measured by Oil Red O staining. Lipolysis was assessed by measuring the amount of glycerol released in the culture media. To evaluate the lipolytic activity of GPC on a physiological condition, GPC was subcutaneously injected to one side of inguinal fat pads for 3 days. Lipolytic activity of GPC was assessed by hematoxylin and eosin staining in adipose tissue. GPC significantly suppressed adipocyte differentiation of 3T3-L1 in a concentration-dependent manner (22.3% inhibition at 4 mM of GPC compared to control). Moreover, when lipolysis was assessed by glycerol release in 3T3-L1 adipocytes, 6 mM of GPC stimulated glycerol release by two-fold over control. Subcutaneous injection of GPC into the inguinal fat pad of mice significantly reduced the mass of fat pad and the size of adipocytes of injected site, and these effects of GPC were more prominent over PPC and AMPL. Taken together, these results suggest that GPC is the potential therapeutic agent as a local fat reducer.

The role of inflammation in adipocytolytic nonsurgical esthetic procedures for body contouring

Background

The adipocytolytic non-surgical esthetic procedures are indicated for the reduction of localized fat and are effective in reducing local adiposity through the ablation of adipocytes with fast and lasting results, besides causing local inflammation.

Objective

This study aimed to characterize the adipocytolytic procedures and correlate the phases of the inflammatory process with the results obtained from such procedures, in order to clarify the role of inflammation triggered by the adipocytolytic procedures and its relation with the lipolytic process, with a focus on body shaping.

Methods

This work is an integrative literature review that presents a total of 72 articles published between 1998 and 2015, derived from the PubMed database, in order to establish a relationship between clinical and basic science research, assuming an important role in medical practice based on evidence.

Results

The results show that the adipocytolytic procedures are characterized by triggering inflammation arising from the disruption of adipocytes by interfering with the lipolytic signaling pathways in both acute and chronic phases of inflammation through the direct action of proinflammatory cytokines or catecholamines. Therefore, inflammation plays an important role in modulating the lipolytic process, influencing body shaping.

Conclusion

The inflammatory process assists the adipolytic process in all stages of inflammation, contributing to the reduction of body contouring.

Deoxycholic acid inhibited proliferation and induced apoptosis and necrosis by regulating the activity of transcription factors in rat pancreatic acinar cell line AR42J

The objective of this study is to investigate the effect of deoxycholic acid (DCA) on rat pancreatic acinar cell line AR42J and the functional mechanisms of DCA on AR42J cells. AR42J cells were treated with various concentrations of DCA for 24 h and also treated with 0.4 mmol/L DCA for multiple times, and then, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay was performed to detect the AR42J cell survival rate. Flow cytometric was used to detect the cell apoptosis and necrosis in AR42J cells treated with 0.4 mmol/L and 0.8 mmol/L DCA. The cells treated with phosphate buffer saline (PBS) were served as control. In addition, the DNA-binding activity assays of transcription factors (TFs) in nuclear proteins of cells treated with DCA were determined using Panomics Procarta Transcription Factor Assay Kit. The relative survival rates were markedly decreased (P < 0.05) in a dose- and time-dependent manner. Compared with control group, the cell apoptosis and necrosis ratio were both significantly elevated in 0.4 mmol/L DCA and 0.8 mmol/L DCA groups (P < 0.01). A significant increase (P < 0.05) in the activity of transcription factor 2 (ATF2), interferon-stimulated response element (ISRE), NKX-2.5, androgen receptor (AR), p53, and hypoxia-inducible factor-1 (HIF-1) was observed, and the activity of peroxisome proliferator-activated receptor (PPAR), activator protein 1 (AP1), and E2F1 was reduced (P < 0.05). In conclusion, DCA inhibited proliferation and induced apoptosis and necrosis in AR42J cells. The expression changes of related genes regulated by TFs might be the molecular mechanism of AR42J cell injury.

Long term assessment of intralipotherapy in Madelung's disease

Madelung's disease is characterised by multiple symmetric abnormal fat masses in the head, neck and upper limbs. Surgical excision or liposuction is the only realistic available option, although palliative in nature. The serial intralipotherapy with phosphatidylcholine/deoxycholate has been proposed as a non-invasive treatment of Madelung's disease. The authors used serial intralipotherapy with phosphatidylcholine/deoxycholate in two patients affected by Madelung's disease. Three injections per lesion per patient were performed with 1 month's interval. Pre- and 6 months’ post-treatment dimensions were assessed with ultrasound scan and patients were observed along a 5 years’ clinical follow-up. A 42.5% average size reduction was reported in all treated lesions. About 33% recurrence rate was observed in the 5 years’ follow-up. We confirm the efficacy of intralipotherapy in the non-invasive palliative treatment of Madelung's disease, as a valid option to reduce the volume and limit the growth of the pathological adipose masses.

Injection of phosphatidylcholine and deoxycholic acid regulates gene expression of lipolysis-related factors, pro-inflammatory cytokines, and hormones on mouse fat tissue

Injection of phosphatidylcholine (PC) and deoxycholic acid (DA) preparation is widely used as an alternative to liposuction for the reduction of subcutaneous fat. Nevertheless, its physiological effects and mechanism of action are not yet fully understood. In this report, PC and deoxycholic acid (DA) were respectively injected into adipose tissue. PC decreased tissue mass on day 7, but DA did not. On the other hand, a decrement of DNA mass was observed only in DA-injected tissue on day 7. Both PC and DA reduced the mRNA expression of adipose tissue hormones, such as adiponectin, leptin, and resistin. In lipolysis-related gene expression profiles, PC increased hormone-sensitive lipase (HSL) transcription and decreased the expression other lipases, perilipin, and the lipogenic marker peroxisome proliferator-activated receptor-γ (PPARγ); DA treatment diminished them all, including HSL. Meanwhile, the gene expression of pro-inflammatory cytokines and a chemokine was greatly elevated in both PC-injected and DA-injected adipose tissue. Microscopic observation showed that PC induced lipolysis with mild PMN infiltration on day 7. However, DA treatment did not induce lipolysis but induced much amount of PMN infiltration. In conclusion, PC alone might induce lipolysis in adipose tissue, whereas DC alone might induce tissue damage.

The effect of phosphatidylcholine and deoxycholate compound injections to the localized adipose tissue: an experimental study with a murine model

Background

Phosphatidylcholine (PPC) and deoxycholate (DCA) compound has been recently used for the purpose of partial lipolysis and is valued for its efficacy and lower invasiveness compared to liposuction and dermolipectomy used previously. In this article, the authors discuss the efficacy of the PPC dissolved in DCA via an experimental rat study model, along with suggesting a useful animal experimental model for the study of adipose tissue and lipolysis.

Methods

Bilateral inguinal fat pads of an experimental rat were elevated with the deep inferior epigastric vessel as the sole vascular pedicle. Normal saline was injected on one side as a control group and a PPC and DCA compound was injected on the other side. After 4 days, the rats were euthanized for microscopic tissue examination. The pathology was scored by a semiquantitative system in 4 categories: normal fat amount, fat necrosis, inflammatory activity, and stage of fibrosis. A Wilcoxon signed-rank test powered by SPSS packet program was used for statistical analysis and to determine significance.

Results

Microscopic examination was performed on the obtained samples, and the experimental data of all four categories showed significant histologic differences compared to the control group. All of the data also showed statistical significance by the Wilcoxon signedrank test (P<0.01).

Conclusions

In the inguinal fat pad rat model, the control group and the experimental group had a differed significantly in the amount of normal fat tissue, inflammation, necrosis, and fibrosis. We recommend the rat inguinal fat pad model used in this study, as it is likely to be useful in related research.

Accelerated healing of cutaneous leishmaniasis in non-healing BALB/c mice using water soluble amphotericin B-polymethacrylic acid

Cutaneous leishmaniasis (CL) is a neglected tropical disease that causes prominent skin scaring. No water soluble, non-toxic, short course and low cost treatment exists. We developed a new water soluble amphotericin B-polymethacrylic acid (AmB-PMA) using established and scalable chemistries. AmB-PMA was stable for 9 months during storage. In vitro, it was effective against Leishmania spp. promastigotes and amastigote infected macrophages. It was also less toxic and more effective than deoxycholate-AmB, and similar to liposomal AmB. Its in vivo activity was determined in both early and established CL lesion models of Leishmania major infection in genetically susceptible non-healing BALB/c mice. Intradermal AmB-PMA at a total dose of 18 mg of AmB/kg body weight led to rapid parasite killing and lesion healing. No toxicity was seen. No parasite relapse occurred after 80 days follow-up. Histological studies confirmed rapid parasite clearance from macrophages followed by accelerated fibroblast mediated tissue repair, regeneration and cure of the infection. Quantitative mRNA studies of the CL lesions showed that accelerated healing was associated with increased Tumour Necrosis Factor-α and Interferon-γ, and reduced Interleukin-10. These results suggest that a cost-effective AmB-PMA could be used to pharmacologically treat and immuno-therapeutically accelerate the healing of CL lesions.

[Injection lipolysis]

A new treatment variation in the spectrum of aesthetic medicine has been investigated worldwide since 2004: so-called injection lipolysis. Advances in knowledge regarding the efficacy and mechanism of action have been achieved especially in Germany because most users are found in Germany when compared on an international level. The reason for this is that the combination of phosphatidylcholine and deoxycholic acid as active substances has been approved for i.v. treatment of fat embolisms. It is thus readily available, but the subcutaneous injection of the drug Lipostabil N® is considered as off-label use. Meanwhile injection lipolysis has become an integral component for many in the practice of aesthetic medicine. The international association of physicians performing lipolysis in the so-called NETWORK-Lipolysis (with more than 2,000 members worldwide) has in particular called for the development of internationally recognized treatment standards and protocols. When the indication for its use adheres to strict criteria and the physicians applying the method have participated in intensive training, subcutaneous injection of phosphatidylcholine/deoxycholic acid represents a meaningful addition to the scope of minimally invasive aesthetic medicine.

[Adipose tissue. Cellular and molecular principles]

For many decades, cutaneous biology research has primarily focused on the dermis and epidermis. In recent years the subcutaneous far has attracted the attention of basic science, cosmetology and industry. Numerous new approaches are in the process of development, enabling us to better understand assembly, differentiation and function of adipose tissue. To understand these developments a background in the cellular and molecular basics of adipose tissue is indispensable. This state-of the art article provides the needed information.

[Complications of injections of hypoosmotic solutes in an underage patient]

Liposuction represents the standard surgical treatment of localized fat excess. Some non-plastic-surgery-board-certified practitioners are likely to offer non-invasive alternatives treatments. We report the clinical case of a 14-year-old female patient who followed a Lipectomy treatment. The Lipectomy technique consists in a hypodermic injection of hypotonic solutions in order to obtain an adipocytes lysis by osmotic shock. No PubMed referenced scientific publication is related to the efficacy or the tolerance of this technique. Postoperative evolution was marked by a polymicrobial subcutaneous abscess that needed two surgical evacuations and 10 days of overnight stay in our department. Through this clinical case, we evoke the possible dangers linked to the application of a non-evaluated medical technique and the necessity of establishing an official validation agency related to innovative techniques in aesthetic medicine and surgery.

Compounds used for 'injection lipolysis' destroy adipocytes and other cells found in adipose tissue

BACKGROUND

A widely applied technique to reduce subcutaneous fat pad size involves subcutaneous injection of a phosphatidylcholine preparation ('injection lipolysis'). As the mode of action is mostly unknown, we planned to study cellular effects of the particular drug used in Germany (Lipostabil(R)).

METHODS

Human preadipocytes, adipocytes, vascular and skeletal muscle cells as well as renal epithelial cells were incubated in the compound, morphological changes were described, and cell vitality was measured.

RESULTS

A strong cytolytic effect of the compound was signified by lipid release and acridine orange staining of dying adipocyte nuclei. When the undiluted compound was used, more than 90% of cell death occurred after 90 s in preadipocytes, after 6 min in vascular smooth muscle cells, skeletal myotubes and renal epithelial cells, and after 15 min in adipocytes. Dilution slowed down cytolysis, but still >50% of the cells disappeared during 30 min incubation. Neither osmotic effects nor differences in medium acidity were responsible for cell death.

CONCLUSION

Injection lipolysis with phosphatidylcholine as the major injected compound reduces subcutaneous fat pad size through cell and tissue destruction. Beside the lack of a clear risk-benefit analysis, applying this technique represents off-label drug use and application of a drug by a contraindicated route.