How can we fight blood cancer more effectively?

Several hundred different treatment combinations to be tested simultaneously outside the body

02-May-2023 - Switzerland

Despite approved treatments being available, multiple myeloma remains incurable. But researchers at ETH Zurich and University Hospital Zurich set out to improve treatment outcomes by testing hundreds of existing therapeutics outside the body to predict their effectiveness.

Berend Snijder Lab / ETH Zürich

Bone-​marrow cells of a multiple myeloma patient. Red cells are healthy monocytes, green and yellow are plasma cells.

Multiple myeloma is a rare blood cancer caused by the uncontrolled multiplication of abnormal plasma cells. These plasma cells are a special type of white blood cells that play an important role in the immune system by producing essential antibodies in the bone marrow and lymph nodes.

Despite an increasing number of approved drugs and treatment approaches such as immunotherapy becoming available, the disease is still not curable. The average life expectancy of patients after diagnosis is only five years.

One of the main challenges is the cancer’s tendency to return even after treatment. This is because treatment makes the cancer cells more resistant to the drugs used, until eventually, after several rounds of treatment, no effective options remain.

To address this issue, ETH researchers have adapted their screening platform to look for ways out of this problem, and thereby offering new hope for more successful treatment outcomes.

Biopsies under the microscope

The researchers are using a high-throughput screening method called pharmacoscopy, developed by Professor Berend Snijder, to test the effectiveness of various treatments on the patient’s cancer cells.

This state-of-the-art method allows for several hundred different treatment combinations to be tested simultaneously outside the body. By analysing the reactions of the cells to each treatment, they can determine which method holds the most promise for each patient.

To do this, the cells from the biopsies are placed in special plates with 384 small wells, each containing a different combination of potential treatment substances. After 24 hours, the cells are stained using different antibodies, and their reactions are evaluated using images generated by automated microscopy. A deep-learning algorithm is then used to identify and classify the cell types. The process is largely automated, allowing for efficient and accurate analysis of the results.

138 biopsies individually tested

The researchers used pharmacoscopy to closely examine 138 bone marrow biopsies from 89 myeloma patients with different stages of multiple myeloma, including newly diagnosed and untreated, as well as patients that underwent multiple treatment rounds.

The goal was to observe the behaviour of cancer cells in response to various approved drugs and drug combinations in each biopsy. Based on the cells’ appearance, the researchers could determine the best treatment option for each patient.

Although the Snijder lab had previously used pharmacoscopy in similar studies on other types of blood cancer, such as lymphomas and leukaemias, the platform had to be adapted for this myeloma study.

Hope for more effective treatments

The groundbreaking work done by the researchers at ETH and University Hospital Zurich offers hope for more effective treatments for multiple myeloma. By using Pharmacoscopy to test hundreds of treatments, the researchers were able to identify new, more effective treatment options for each patient.

This new personalized medicine approach is transferable to the clinic and can thus help doctors find the best option for their patients at an early stage. "First, however, we will have to validate the method further in clinical trials," says Snijder.

Now, the Snijder lab wants to develop the platform further to expand its use to solid tumours. Unlike blood cancers, solid tumours must first be dissociated to a certain degree before they can be tested in the 384-well plate format. They are currently adapting the screening platform for brain tumours, among others.

Original publication

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