San Diego, Ca – University of Cincinnati Cancer Center researchers will present abstracts at the American Society of Hematology (ASH) Annual Meeting, held Dec. 9-12 in San Diego, California.
Trial finds new drug shows promise to treat Chronic Lymphocytic Leukemia (CLL)
Phase 2 clinical trial results suggest a new drug has the potential to be the most selective covalent inhibitor treatment available for CLL and offers potential for improved efficacy and safety.
John Byrd, MD, said a group of drugs known as BTK inhibitors has become the backbone of treatment for chronic lymphocytic leukemia (CLL) and small lymphocytic lymphoma (SLL). The trial tested a new BTK inhibitor, TL-895, that has selective action against BTK.
The multicenter trial enrolled a total of 84 patients, including those whose CLL had returned or stopped responding to treatment (relapsed/refractory) and those who had not received any previous treatments (treatment naive). Patients were randomized to receive either 100 or 150 milligrams of TL-895 twice a day in each patient group.
At a median follow-up of 23 months, 86% of relapsed/refractory patients taking the 100 milligram dose and 81% of those taking 150 milligram doses had at least a partial response to the drug. At a median follow-up of eight months, 86% of treatment naive patients at both doses had at least a partial response, but those in the 150 milligram group had a faster response. Safety in both groups of patients was exceptional.
Overall, Byrd said TL-895 treatment led to rapid reduction of leukemic cells, with earlier and deeper responses than expected for a covalent BTK inhibitor. Relapsed/refractory patients have been able to remain in remission, and the drug was found to be safe, with a low incidence of adverse reactions.
“While our current approved covalent BTK inhibitors including the first-generation agent ibrutinib and second-generation inhibitors acalabrutinib and zanabrutinib represent a major therapeutic advance for CLL, TL-895 is even more selective for BTK and offers opportunity for both improved efficacy and safety over other agents,” said Byrd, Gordon and Helen Hughes Taylor endowed chair and professor of internal medicine in UC’s College of Medicine. “We are excited for what TL-895 represents as a penultimate second generation BTK inhibitor.”
Research identifies potential combination therapy to improve Acute Myeloid Leukemia treatment
IRAK4 is a protein known to help drive growth of acute myeloid leukemia (AML) cells through overactivation, making it a potential target for new treatments. Unfortunately, initial trials suggest treatments that neutralize its signaling may have limited effect on their own (as monotherapy).
Cancer Center researcher Eric Vick, MD, PhD, and colleagues sought to identify which target would be most effective at killing cells after being weakened by the reduction of IRAK4 signaling.
“After you have combined the loss of IRAK4 with different pharmacologic agents, you create a situation that is lethal for the cells,” said Vick, a clinical fellow working in Daniel Starczynowski’s lab at Cincinnati Children’s who will join UC’s faculty in January.
Vick said the team tested more than 2,400 small molecules to compare their effectiveness in killing normal AML cells and those that did not have overactive IRAK4. They found one compound was especially effective at killing AML cells by reducing the levels of a protein called c-myc that drives cancer growth.
“It degrades c-myc using the cell’s machinery, and as a result, we’re able to drop the levels of c-myc to a point where the cells can’t survive,” Vick said. “Many cancer cells rely on high levels of c-myc in order to survive, so part of what we’ve been studying is how much AML requires for survival. The loss of IRAK4 signaling allows a faster and lower reduction than would normally be possible in these cells.”
Many drugs have been developed to target c-myc without much clinical success, so Vick said moving forward the team will use this class of protein degraders with IRAK4 inhibitors as an alternative approach to target leukemia.
“What we’re hoping to do is create a situation where we can sensitize patients with leukemia with a relatively mild, very tolerable drug — the IRAK4 inhibitor — and then treat with a second, more robust drug that can wipe out all the leukemia cells,” he said. “As always, we’re trying to extend remissions and develop a cure.”
Overall Sickle Cell death rate declining, but increasing among young adults
A review of U.S. mortality statistics found the sickle cell disease (SCD) mortality rate has significantly decreased over the past 40 years as treatments have improved, but the mortality rate has increased for young adults.
SCD is a blood disorder that can cause a variety of symptoms in patients, including stroke and cognitive impairment. It is one of the most common inherited disorders in the U.S. that primarily affects people of African ancestry, with 10% of African Americans having sickle cell trait and 1 in 365 having SCD.
The University of Cincinnati’s Kristine Karkoska, MD, said the most significant improvement to SCD treatment in recent decades was the introduction of the medication hydroxyurea. Other improvements in care include the implementation of universal newborn screening in 2006 that allows for early diagnosis and establishment of care and the establishment of comprehensive SCD care centers, particularly in pediatric settings.
From 2010-2020, the overall SCD crude mortality rate was 1.1 per 100,000 Black individuals, a decrease from 1.2 per 100,000 from 1999-2009. Of the 5,272 SCD-related deaths from 2010-20, 61% listed SCD as the primary cause of death, with cardiovascular disease (28%), accidents and cerebrovascular disease (both 7%), malignancy (6%), septicemia (4.8%) and renal disease (3.8%) being the next most common primary causes of death.
“The decrease in overall mortality was what we expected and had hoped to see,” said Karkoska, assistant professor of internal medicine in UC’s College of Medicine. “I was most struck by the degree of non-SCD related chronic diseases that were included in mortality data.”
The crude mortality rate for patients aged 15-19 increased from 0.9 per 100,000 in 1999-2009 to 1.4 per 100,000 in 2010-20, which Karkoska said highlights the need for better care as patients transition from pediatric to adult care. While there are no easy fixes and research is ongoing to improve the transition of care for many chronic diseases that begin in childhood, Karkoska said communication between pediatric and adult programs is vital.
“In addition, the pediatric program needs to treat the young person as an adult, while the adult program needs to recognize that newly-transitioned young adults often require additional oversight initially,” she said. “I have been uniquely positioned to see this as a pediatric hematologist who now cares for young adults.”
New drug targets mutation, helps overcome treatment resistance in Acute Myeloid Leukemia lab models
More than 30% of acute myeloid leukemia (AML) patients have a mutation called FLT3 that helps the cancer grow and thrive. There are currently available medications that target this mutation that are effective, but tumor cells often develop additional mutations that lead to drug resistance.
Researchers including Ola A. Elgamal, PhD, in the Cancer Center’s Leukemia and Drug Development Lab are developing new therapies to overcome this drug resistance and make treatments more effective. Elgamal and colleagues particularly focused on targeting the most common mutation that leads to resistance, known as a “gatekeeper” mutation.
The research team tested a new compound in the lab called E2082-0047 and found it works “very well” against the FLT3 gatekeeper mutation and shows promise as a treatment that could help lead to long-term survival for patients with AML. A Phase 1 clinical trial in healthy volunteers is currently underway to determine the best dose of the treatment in humans, Elgamal said.
“That will allow us to move forward and test it in AML patients that have a positive FLT3 mutation,” said Elgamal, assistant professor in the UC College of Medicine’s Division of Hematology/Oncology. “We are also using some novel animal models to understand how the immune system contributes to the prolonged response to this type of therapy.”
Contact
Tim Tedeschi
University of Cincinnati
[email protected]