Isolation of interstitial fluid from skeletal muscle and subcutis in mice using a wick method

In vitro modelling of intramuscular injection site events

INTRODUCTION

Intramuscular (IM) injections deliver a plethora of drugs. The majority of IM-related literature details dissolution and/or pharmacokinetic (PK) studies, using methods with limited assessments of post-injection events that can impact drug fate, and absorption parameters. Food and Drug Association guidelines no longer require preclinical in vivo modeling in the U.S.A. Preclinical animal models fail to correlate with clinical outcomes, highlighting the need to study, and understand, IM drug fate in vitro using bespoke models emulating human IM sites. Post-IM injection events, i.e. underlying processes that influence PK outcomes, remain unacknowledged, complicating the application of in vitro methods in preclinical drug development. Understanding such events could guide approaches to predict and modulate IM drug fate in humans.

AREAS COVERED

This article reviews challenges in biorelevant IM site modeling (i.e. modeling drug fate outcomes), the value of technologies available for developing IM injectables, methods for studying drug fate, and technologies for training in performing IM administrations. PubMed, Web-of-Science, and Lens databases provided papers published between 2014 and 2024.

EXPERT OPINION

IM drug research is expanding what injectable therapeutics can achieve. However, post-injection events that influence PK outcomes remain poorly understood. Until addressed, advances in IM drug development will not realize their full potential.

Prediction of subcutaneous drug absorption - characterization of subcutaneous interstitial fluids as a basis for developing biorelevant in vitro models

Unlike orally administered drugs, the absorption profile of subcutaneously injectable drugs in humans is difficult to predict from preclinical studies. Since the subcutaneous interstitial fluid (ISF) is the first fluid interacting with the administered formulation before the respective drug is absorbed, it could critically affect bioavailability. The aim of the present study was to gain a better understanding of the similarities and differences of ISF of different species. For this purpose, ISF was isolated from subcutaneous tissues of five preclinical animal species, i.e., mice, rats, minipig, landrace pig, non-human primates, and humans, using a centrifugation method, and characterized with respect to its major constituents and physicochemical properties. The results show trends between animal species, with ISF from non-human primates differing significantly from that of the other preclinical species for most parameters analyzed and showing similarities to ISF of human origin. Although from a statistical point of view it will be necessary to further increase the existing data sets, the presented data provide valuable information for the development of biorelevant in vitro models to predict the in vivo performance of subcutaneously administered formulations, as they provide fundamental information for the design of biorelevant ISF media for both preclinical species and humans.

Interstitial Fluid and Lymph Formation and Transport: Physiological Regulation and Roles in Inflammation and Cancer

The interstitium describes the fluid, proteins, solutes, and the extracellular matrix (ECM) that comprise the cellular microenvironment in tissues. Its alterations are fundamental to changes in cell function in inflammation, pathogenesis, and cancer. Interstitial fluid (IF) is created by transcapillary filtration and cleared by lymphatic vessels. Herein we discuss the biophysical, biomechanical, and functional implications of IF in normal and pathological tissue states from both fluid balance and cell function perspectives. We also discuss analysis methods to access IF, which enables quantification of the cellular microenvironment; such methods have demonstrated, for example, that there can be dramatic gradients from tissue to plasma during inflammation and that tumor IF is hypoxic and acidic compared with subcutaneous IF and plasma. Accumulated recent data show that IF and its convection through the interstitium and delivery to the lymph nodes have many and diverse biological effects, including in ECM reorganization, cell migration, and capillary morphogenesis as well as in immunity and peripheral tolerance. This review integrates the biophysical, biomechanical, and biological aspects of interstitial and lymph fluid and its transport in tissue physiology, pathophysiology, and immune regulation.

Lymphotoxin-alpha contributes to lymphangiogenesis

Lymphotoxin-α (LTα), lymphotoxin-β (LTβ), and tumor necrosis factor-α (TNFα) are inflammatory mediators that play crucial roles in lymphoid organ development. We demonstrate here that LTα also contributes to the function of lymphatic vessels and to lymphangiogenesis during inflammation. LTα(-/-) mice exhibited reduced lymph flow velocities and increased interstitial fluid pressure. Airways of LTβ(-/-) mice infected with Mycoplasma pulmonis had significantly more lymphangiogenesis than wild type (WT) or LTα(-/-) mice, as did the skin draining immunization sites of LTβ(-/-) mice. Macrophages, B cells, and T cells, known sources of LT and TNFα, were apparent in the skin surrounding the immunization sites as were LTα, LTβ, and TNFα mRNAs. Ectopic expression of LTα led to the development of LYVE-1 and Prox1-positive lymphatic vessels within tertiary lymphoid organs (TLOs). Quantification of pancreatic lymphatic vessel density in RIPLTαLTβ(-/-) and WT mice revealed that LTα was sufficient for inducing lymphangiogenesis and that LTβ was not required for this process. Kidneys of inducible LTα transgenic mice developed lymphatic vessels before the appearance of obvious TLOs. These data indicate that LTα plays a significant role in lymphatic vessel function and in inflammation-associated lymphangiogenesis.

Transcapillary exchange: role and importance of the interstitial fluid pressure and the extracellular matrix

This review will summarize current knowledge on the role of the extracellular matrix (ECM) in general and on the interstitial fluid pressure (P(if)) in particular with regard to their importance in transcapillary exchange. The fluid volume in the interstitial space is normally regulated within narrow limits by automatic re-adjustment of the interstitial hydrostatic and colloid osmotic pressures in response to perturbations in capillary filtration and by the lymphatics. Contrary to this commonly accepted view, P(if) can become an active force and create a fluid flux across the capillaries in several inflammatory reactions and trauma situations rather than limit the changes occurring. The molecular mechanisms involved in the lowering of P(if) include the release of cellular tension exerted on the collagen and microfibril networks in the connective tissue via the collagen-binding beta(1)-integrins, thereby allowing the glycosaminoglycan ground substance, which is normally underhydrated, to expand and take up fluid. Several growth factors and cytokines, including the platelet-derived growth factor BB, are able to reverse a lowering of P(if) and restore the normal compaction of the ECM. The magnitude of the lowering of P(if) varies with the inflammatory response. In several inflammatory reactions, a lowering of P(if) to -5 to -10 mmHg is seen, which will increase capillary filtration by 10-20 times since the normal capillary filtration pressure is usually 0.5-1 mmHg (skin and skeletal muscle). Unless this lowering of P(if) is taken into account, the enhanced solute flux resulting from an inflammatory response will be ascribed to an increased capillary permeability.

Dexamethasone modifies the susceptibility to serum cytotoxicity and increases the metastatic efficiency of a colon carcinoma cell line

Metastatic inefficiency is a phenomenon by which a majority of tumor cells is lost in the blood stream during the metastatic process. We investigated the effects of dexamethasone (DEX), a synthesized glucocorticoid, on the serum susceptibility of a colon carcinoma cell line, HT-29, with respect to metastatic inefficiency. The susceptibility to serum cytotoxicity of these carcinoma cells is possibly an important factor in metastatic inefficiency. In this study, we used glucocorticoid because it modifies the function of the plasma membrane and has been shown to enhance the hematogenous metastasis of some tumor cells. Using HT-29 cells that had been treated with DEX in vitro, the following factors were evaluated: the metastasis of intrasplenic injected cells; in vitro and in vivo proliferation; motility; the production of matrix metalloproteinases (MMPs); and the expression of the membrane complement regulatory proteins CD46, CD55, and CD59. The number of viable cells in the liver after an intraportal injection of tumor cells was determined by the expression of human beta-globin mRNA that is aberrantly expressed in HT-29 cells. In addition, we investigated 100% serum-induced proliferation, susceptibility, and apoptosis. Treatment with DEX was found to accelerate liver metastasis; here, the number of metastatic colonies and the weight of the liver were both significantly increased in DEX-treated HT-29 (HT-29DEX) cells. In contrast, there was no difference in terms of cell motility; the production of MMPs; or the expression of CD46, CD55, or CD59 between the HT-29 and HT-29DEX cells. The HT-29DEX cells exhibited enhanced proliferation in the serum, as well as resistance to cytotoxicity when exposed to 100% serum. In addition, DEX slightly inhibited serum-induced apoptosis. Finally, the expression of colon cancer-derived beta-globin mRNA was detectable 24 h after intravenous injection, but only in samples obtained from the HT-29DEX-, but not in those from the HT-29-inoculated mice. These results indicate that DEX reduced the metastatic inefficiency of the HT-29 cells, resulting in a hematogenous metastasis-prone phenotype. It is thus expected that the acquisition of resistance against serum cytotoxicity is among the mechanisms that contribute to the efficiency of hematogeneous metastasis.

Transcapillary fluid balance consequences of missing initial lymphatics studied in a mouse model of primary lymphoedema

To investigate the phenotypic consequences of a deranged lymphangiogenesis in relation to tissue fluid accumulation and the possible role of inflammation in the pathogenesis of lymphoedema, we measured determinants of transcapillary fluid filtration and inflammatory mediators in the interstitial fluid in genetically engineered Chy mice, a model for primary congenital lymphoedema (Milroy's disease). Although initial lymphatics were not present in dermis in any of the areas studied (fore paw, hind paw, thigh and back skin) interstitial fluid pressure (P(if)), measured with micropipettes, and tissue fluid volumes were significantly increased only in the areas with visible swelling - the fore and hind paw, whereas interstitial colloid osmotic pressure (COP(if)) was increased in all the skin areas examined. A volume load of 15% of body weight resulted in a more pronounced increase in P(if) as well as a four-fold increase in interstitial fluid volume in Chy relative to wild-type (wt) mice, showing the quantitative importance of lymphatics for fluid homeostasis during acute perturbations. A similar level of proinflammatory markers in interstitial fluid in early established lymphoedema (3-4 months) in Chy and wt suggests that inflammation does not have a major pathogenetic role for the development of lymphoedema, whereas a reduced level of the immunomodulatory cytokine interleukin (IL)-4 may result in a reduced immunological defence ability and thus lead to the increase in inflammatory cytokines IL-2 and IL-6 observed at a later stage (11-13 months). Our data suggest that primary lymphoedema results in a high interstitial fluid protein concentration that does not induce an interstitial inflammatory reaction per se, and furthermore shows the paramount importance of the initial lymphatics in tissue fluid homeostasis, especially during perturbations of transcapillary fluid balance.