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18 August 2021 | Story André Damons | Photo André Damons
Dr Osayande Evbuomwan is a Senior Lecturer and medical specialist in nuclear medicine in the Department of Nuclear Medicine, Faculty of Health Sciences, at the University of the Free State (UFS).

The University of the Free State (UFS) Department of Nuclear Medicine has, for the first time, started using Lutetium 177 PSMA (Lu-177 PSMA) therapy for the treatment of metastatic castrate-resistant prostate cancer (MCRPC) – an advanced stage of prostate cancer.

The UFS and the Free State province are now joining other South African universities, such as the University of Pretoria, the University of the Witwatersrand, and other provinces in using this method to treat MCRPC patients. 

Dr Osayande Evbuomwan, a Senior Lecturer and medical specialist in the Department of Nuclear Medicine, Faculty of Health Sciences, says they have started treating their first MCRP patient (first cycle) with peptide receptor radionuclide therapy (PRRT) on 15 July. It is the first time that Lutetium 177 PSMA – a type of PRRT used for treating patients with MCRPC – has been used in the Free State. This method is used on MCRPC patients who are not eligible for chemotherapy or have failed first- or second-line chemotherapy.

Expertise and funds are now available for this treatment

Dr Evbuomwan was trained and exposed to this therapy at the University of the Witwatersrand during his registrar training in nuclear medicine. When he joined the UFS in 2019, he – with the always available help of the Head of Department, Dr Gerrit Engelbrecht – pushed for the therapy to be used in the department. 

“We in the Department of Nuclear Medicine are happy that expertise is now available and that some funds have been released for this treatment to commence. The index patient is very sick with MCRPC and was too sick to qualify for first-line chemotherapy. Each patient will need about four-six cycles for complete treatment. The patient is being treated in the Department of Nuclear Medicine at the Universitas Academic Hospital and Annex.” 

“We are hoping that he will be able to complete at least four cycles and respond well to the treatment. We believe that the ability to administer this treatment now is good news for the Free State, as the people of the Free State also deserve to be exposed to this level of treatment. We are hoping that the government will continue to provide more funds for more of these patients to be treated in our facility,” says Dr Evbuomwan.

It was budgeted to treat five patients (20 cycles), with each cycle (just the Lu-177 PSMA) costing more than R50 000. 

A googled image from the internet of a case before, during, and after completing the full course of therapy. The first image is before
treatment and the last image is after completing treatment, while the images in between are during treatment.
(Source: Google) 

Prostate cancer one of the leading causes of morbidity and mortality

Dr Evbuomwan says prostate cancer is one of the leading causes of morbidity and mortality in the world, including South Africa. When it progresses to the advanced stage of MCRPC, the prognosis becomes bad. 

Dr Evbuomwan explains that there are various conventional systemic therapies, including first- and second-line chemotherapy that could be used to treat patients at this bad stage. However, not all patients are fit for chemotherapy. The few who are fit, according to Dr Evbuomwan, usually end up failing the first-line chemotherapy, which has a lot of undesirable side effects and require long-stay hospital admissions. 

Only a few centres are able to offer second-line chemotherapy. So many of these patients end up suffering from prolonged bone pains before eventually dying from the disease.

PRRT is a targeted nuclear medicine therapy that offers the opportunity to deliver very high levels of radiation specifically to cancer cells, because these cancer cells express specific receptors to which certain peptides can bind. This specificity to cancer cells offers the advantage of providing lower doses of radiation and damage to normal organs and tissues, a characteristic that conventional therapies do not offer, explains Dr Evbuomwan.  

According to him, Lutetium 177 PSMA (Lu-177 PSMA) is a type of PRRT used for treating patients with MCRPC, who are not eligible for chemotherapy or have failed first-line chemotherapy. Numerous research studies around the world have proven that this treatment improves quality of life, slows down disease progression, and improves overall survival, with little or very tolerable side effects in most patients. 

The University of Pretoria is one of the pioneers of this treatment in the world, having done a lot of research with it since 2017. Other provinces such as the Western Cape and KwaZulu-Natal have also recently become involved with the therapy. This therapy is expensive and requires a lot of expertise. It also involves the input of a multidisciplinary team (MDT), which must at least include a nuclear medicine physician, a radiation oncologist, and a urologist. The Departments of Urology and Radiation Oncology at the UFS were also instrumental in the initiation of the therapy and form part of the MDT team at the UFS in the management of these patients.

Treatment puts department, university, and hospital on the map

Dr Evbuomwan says the ability to administer this treatment puts the department, the UFS, and the hospital on the map, alongside other top universities within and outside the country. “It also creates an avenue for us to gather data for research purposes and for publications. We are now able to offer a promising, safe, and highly efficacious therapy for patients with MCRPC in the Free State. Some of these patients no longer need to travel to other provinces to get the treatment.”

There are plans to expand the treatment to more patients – and hospital management, who were present at the first treatment, are excited and looking forward to the outcome of this current treatment.

Watch video below:

News Archive

Nuclear Medicine on the forefront of cancer research
2017-07-10

Description: Nuclear Medicine on the forefront of cancer research Tags: Nuclear Medicine, cancer research, Dr Je’nine Horn-Lodewyk’s, tumour detection method, cancer, Department of Nuclear Medicine 

Dr Je’nine Horn-Lodewyk’s tumour detection method
could be the cost-effective breakthrough needed to decrease
the mortality rate in breast cancer patients.
Photo: Anja Aucamp

The field of Nuclear Medicine in South Africa and the rest of the world are expanding rapidly due to the development of hybrid cameras and new radiopharmaceuticals. These developments have a huge impact on the diagnosis and therapy of cancer.

The most advanced of these cameras, Positron emission tomography combined with normal CTs (PETCT), are not yet widely available in South Africa due to the cost of the cameras and the radiopharmaceuticals. A more cost-effective alternative can be of great benefit. To achieve this, the focus should be on developing new radiopharmaceuticals that can be used with the current cost-effective gamma cameras, according to University of the Free State researcher, Dr Je’nine Horn-Lodewyk from the Department of Nuclear Medicine.

Fluorodeoxyglucose (18F-FDG), a radiolabelled glucose analogue, is currently the radiopharmaceutical most commonly used in PET/CT imaging for mainly oncology indications. Although it is considered the gold standard for imaging in several malignancies, it does have certain disadvantages. An 18F-FDG PET/CT diagnostic imaging study can cost between R25 000 and R35 000 for a single patient in the private sector. The 18F-FDG is also more radioactive, which requires much stricter handling and shielding to avoid high radiation dosages to staff and patients.

Successful research potential innovative solution
In the search for the ideal radiopharmaceutical for tumour detection, the South African National Nuclear Energy Corporation (Necsa) developed a local synthesis process for ethylenedicysteine-deoxyglucose (EC-DG). EC-DG is also a glucose analogue similar to FDG. They succeeded in labelling the compound with Technetium-99-metastable-pertechnetate (99mTcO4-), the most common nuclear medicine isotope used for approximately 95% of nuclear medicine procedures, creating 99mTc-EC-DG.

In partnership with Dr Horn-Lodewyk, this compound was successfully used in various animal models and clinical scenarios, resulting in approval by the Medicine Control Council to use it in a human study. Research is also planned in order to investigate diagnostic accuracy in other cancers like lymphoma.  The end result of this research can produce a radiopharmaceutical that is cost effective, does not require the use of costly specialised equipment, has no significant side-effects, no special patient preparation, renders late imaging possible, and has decreased radiation risks.

Dr Horn-Lodewyk is grateful for the support of her mentor, Prof Anton Otto, as well as Dr Gert Engelbrecht, Head of the Department of Nuclear Medicine, Prof Jan Rijn Zeevaart from North-West University’s Preclinical Drug Development Platform and Necsa, and Judith Wagener from Necsa. This innovative research would also not have been possible without the financial assistance of Dr Glen Taylor and Eleanor van der Westhuizen in the Directorate of Research Development.

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