On the fluid dynamics of a laboratory scale single-use stirred bioreactor.

The commercial success of mammalian cell-derived recombinant proteins has fostered an increase in demand for novel single-use bioreactor (SUB) systems that facilitate greater productivity, increased flexibility and reduced costs (Zhang et al., 2010). These systems exhibit fluid flow regimes unlike those encountered in traditional glass/stainless steel bioreactors because of the way in which they are designed. With such disparate hydrodynamic environments between SUBs currently on the market, traditional scale-up approaches applied to stirred tanks should be revised. One such SUB is the Mobius® 3 L CellReady, which consists of an upward-pumping marine scoping impeller. This work represents the first experimental study of the flow within the CellReady using a Particle Image Velocimetry (PIV) approach, combined with a biological study into the impact of these fluid dynamic characteristics on cell culture performance. The PIV study was conducted within the actual vessel, rather than using a purpose-built mimic. PIV measurements conveyed a degree of fluid compartmentalisation resulting from the up-pumping impeller. Both impeller tip speed and fluid working volume had an impact upon the fluid velocities and spatial distribution of turbulence within the vessel. Cell cultures were conducted using the GS-CHO cell-line (Lonza) producing an IgG4 antibody. Disparity in cellular growth and viability throughout the range of operating conditions used (80-350 rpm and 1-2.4 L working volume) was not substantial, although a significant reduction in recombinant protein productivity was found at 350 rpm and 1 L working volume (corresponding to the highest Reynolds number tested in this work). The study shows promise in the use of PIV to improve understanding of the hydrodynamic environment within individual SUBs and allows identification of the critical hydrodynamic parameters under the different flow regimes for compatibility and scalability across the range of bioreactor platforms.

Cardiotoxicity in the SCID mouse following administration of doxorubicin and cyclosporin A.

Multiple myeloma is a plasma cell malignancy which is generally incurable in spite of a high initial response to chemotherapy. Relapsing disease commonly heralds an increase in the incidence of drug resistance which is often mediated by the product of the MDR-1 gene, P-glycoprotein (Pgp). One approach to modulating drug resistance due to Pgp overexpression has involved the use of agents known as chemomodulators which inhibit its function. We have developed a human xenograft model of multiple myeloma using the SCID mouse to evaluate the efficacy and toxicities of new MDR-1 chemomodulators. Cyclosporin A (CsA) is a widely used immunosuppressant which has been demonstrated to be a potent inhibitor of Pgp in vitro at concentrations which are clinically achievable. Preliminary studies revealed an acute toxicity in our SCID model which was associated with the combination of CsA and doxorubicin, and which was not observed with either drug alone, nor with cremaphor, the vehicle for CsA. In the current study, non-tumor bearing SCID mice were dosed with doxorubicin or the combination of doxorubicin with cremaphor, verapamil or CsA. Animals were sacrificed and tissues harvested for morphologic examination and for HPLC analysis of doxorubicin levels. In all tissues examined, there was a marked increase in tissue levels of doxorubicin when combined with CsA. Results also revealed a higher incidence and severity of myocardial damage in those animals receiving the combination of doxorubicin and CsA than in those receiving other combinations. The elevations in tissue levels observed with doxorubicin and CsA may contribute to the acute toxicities observed in the SCID mouse model.

Severe combined immunodeficiency (SCID) mouse modeling of P-glycoprotein chemosensitization in multidrug-resistant human myeloma xenografts.

We have established a reproducible in vivo model of human multiple myeloma in the severe combined immunodeficiency (SCID) mouse using both the drug-sensitive 8226/S human myeloma cell line and the P-glycoprotein-expressing multidrug-resistant 8226/C1N subline. As demonstrated previously, the SCID mouse is well suited as a model for myeloma because: (a) human SCID xenografts are readily attained; (b) human myeloma xenografts are readily detected by their immunoglobulin secretion; and (c) differential therapy effects in drug-sensitive versus drug-resistant cell lines are readily demonstrable by monitoring mouse urinary human immunoglobulin output. In the current study, we have utilized this model to evaluate the in vivo efficacy of chemomodulators of P-glycoprotein-related multidrug resistance. In our initial experiments, doxorubicin alone was effective in treating the 8226/S human myeloma xenografts but had no effect on the drug-resistant 8226/C1N xenografts, in the absence of the chemosensitizing agent verapamil. In subsequent experiments, the combination of verapamil and doxorubicin resulted in both a decrease in human lambda light chain urinary excretion and an increase in survival of those animals bearing the 8226/C1N tumor. The median survival time of animals injected with 8226/C1N cells and subsequently treated with doxorubicin was 48.6 +/- 7 days, which compared to a survival of 89.6 +/- 18 days in animals receiving the 8226/S cell line and treated with doxorubicin alone (P < 0.001). When verapamil was added to the treatment regimen of those animals bearing the 8226/C1N xenografts, there was a 179% increase in their life span (P < 0.001), which corresponded with the observed decreased light chain in the urine. In animals receiving multiple courses of chemotherapy, an attenuated response to verapamil and doxorubicin was observed, in a manner analogous to the clinical setting of human drug-resistant myeloma escape from chemosensitivity. The SCID human myeloma xenograft model thus offers a means of evaluating the in vivo efficacy and potential toxicities of new therapeutic approaches directed against P-glycoprotein in multidrug-resistant human myeloma.

An in vivo model of human multidrug-resistant multiple myeloma in SCID mice.

We have established a reproducible in vivo model of human multiple myeloma in the severe combined immunodeficient (SCID) mouse using both the RPMI 8226 human myeloma cell line and the P-glycoprotein-expressing multidrug-resistant 8226/C1N subline. SCID mice 5 to 8 weeks of age were injected intraperitoneally with either 8226 drug-sensitive or P-glycoprotein-expressing multidrug-resistant myeloma cells (8226/C1N). Tumors were detected within 5 days after injection by the presence of human lambda light chain excretion in the mouse urine. Growth of the tumor was observed primarily in the abdominal cavity with spread to the abdominal organs. The anti-neoplastic agent doxorubicin was effective in treating the drug-sensitive 8226 human-SCID xenografts but had no effect on the multi-drug-resistant 8226/C1N human-SCID xenografts. In the 8226-sensitive xenografts, treatment with doxorubicin resulted in a sharp decline in the concentration of human lambda light chain being excreted in the mouse urine. This correlated with an increased survival of the drug-treated animals. This mouse model offers an in vivo means of evaluating efficacy and toxicity of new therapeutic approaches, including development of chemosensitizers directed against P-glycoprotein in multidrug-resistant myelomas.

Long-term engraftment of fresh human myeloma cells in SCID mice.

Using highly purified myeloma cells from patient bone marrow, we established human-murine myeloma chimeras in severe combined immunodeficiency (SCID) mice and documented secretion of monoclonal human immunoglobulins (Hulgs) in the mice for up to 299 days. Monoclonality of circulating Hulgs was found only when highly purified myeloma cells were injected intraperitoneally. In contrast, injection of unfractionated myeloma marrow led to the development of polyclonal Hulgs in the SCID mice. The criteria for myeloma engraftment included prolonged presence of monoclonal Hulgs in the sera of SCID mice and/or detection of human myeloma cells in their tissues by immunohistochemical examination. Ninety-one percent (10/11) of the fresh purified myeloma specimens engrafted in the SCID mice. Fifty-five percent (6/11) of the patient samples resulted in human B-cell grafts, and 45% (5/11) were identifiable as human myeloma chimeras. Pathologic studies showed that most human plasmacytes were located in the peritoneal cavity but metastatic infiltrates were also found in other organs in 69% of the SCID-human myeloma chimeras. This chimeric model should provide a useful tool for characterization of growth modulation and microenvironmental interactions as well as a means of testing new therapeutic approaches to multiple myeloma.

Growth and dissemination of human malignant melanoma cells in mice with severe combined immune deficiency.

BACKGROUND: The severe combined immune deficiency (SCID) mouse is lacking mature B and T lymphocytes and may be permissive for human tumor growth and metastasis. EXPERIMENTAL DESIGN: SCID mice received human melanoma cells of diverse origins including: 2 established cell lines, 4 early passage cell lines, and fresh or cryopreserved cells obtained directly from 9 patient biopsies. They were introduced into SCID mice via intraperitoneal, subcutaneous and intravenous injections. RESULTS: Tumor growth occurred with each of the 15 melanoma specimens for a take rate of 100% considering cell source. In addition, 60% of the 102 total mice injected displayed tumor growth in at least one site. The most consistent tumor growth (77%) occurred after intraperitoneal injection. Tumors developed in 41 and 48% of mice injected subcutaneously and intravenously, respectively. The mice developed both local tumor growth with palpable tumor nodules at injection sites and hematogenous and/or lymphatic dissemination to multiple sites in the abdominal and thoracic cavities. The number of metastases per animal averaged 16.3 and the number per organ ranged from 1 to 38. Melanotic and amelanotic tumor nodules obtained from a single patient retained their original characteristics with regard to melanin production after passage in the SCID mouse. The appearance of the human melanoma cells in SCID mouse tissues ranged from implants on the organ capsule to frank parenchymal organ involvement and vascular invasion. Some small foci of tumor were only detected using immunohistochemistry with monoclonal antibodies against the S-100 and HMB-45 to melanoma-related antigens. CONCLUSIONS: We conclude that the SCID mouse consistently supports growth, invasion, and metastatic spread of human melanoma cells, including specimens obtained from fresh patient biopsies. The SCID mouse will serve as a relevant in vivo model for studying the biology of human malignant melanoma and screening new therapeutic agents.

Effect of caloreen supplementation on some haematological values and urinary iron excretion during protein-energy malnutrition.

The effect of caloreen (glucose polymer) supplementation on indicators of iron status during protein-energy malnutrition was studied. Sixty-four children with moderate protein energy malnutrition (PEM) were fed diets supplemented with caloreen or starch (control) for 14 days, following which iron status as packed cell volume (PCV), haemoglobin (Hb), serum iron, total iron binding capacity (TIBC), serum ferritin, and urinary iron levels were determined. Caloreen supplementation significantly increased (P less than 0.05). PCV, serum iron and serum ferritin and decreased (P less than 0.05) TIBC. Also, there was a tendency for Hb to increase and urinary iron to decrease in this group, but these changes were not statistically significant. Such changes were not observed in the starch-placebo-supplemented group. It is concluded that caloreen supplementation to PEM children increases body iron status. These increases in the indices of iron status may contribute to an early recovery of anaemia associated with PEM. Prolonged supplementation of a regular diet with glucose early in the development of PEM may retard the development and severity of anaemia in children.